CN113454099A - Detection of colon neoplasia in vivo using near infrared peptides targeted to overexpress cMET - Google Patents

Abstract

The present disclosure provides peptides, including marker peptides, that selectively bind to cMet proteins. The disclosure also provides methods of detecting dysplastic cells and tissues, such as in the colon, providing early identification of precancerous and cancerous tissues.

Description

Detection of colon neoplasia in vivo using near infrared peptides targeted to overexpress cMET

Cross Reference to Related Applications

This application claims priority to provisional united states patent application 62/808,637 filed on 21/2/2019, the entire contents of which are incorporated herein by reference.

Statement of government interest

The invention was made with government support under CA193377 awarded by the National Institutes of Health. The government has certain rights in the invention.

Incorporation of materials for electronic delivery by reference

The sequence listing, which is part of this disclosure, is submitted concurrently with the specification as a text file. The name of the text file containing the sequence listing is "53791 a _ seqliking.txt", which was created on day 2, month 13 of 2020 and has a size of 828 bytes. The subject matter of the sequence listing is incorporated herein by reference in its entirety.

Technical Field

The present disclosure relates to peptide agents, methods of using the peptide agents to detect precancer (dysplasia) or cancer, and methods of using the peptide agents to target dysplasic or cancerous colon cells.

Background

Colorectal cancer (CRC) is the third most common cause of cancer and the fourth leading cause of tumor death worldwide. It accounts for approximately 8% of all cancer deaths, with 693,900 estimated to die in 2012^1-4. Most patients have developed advanced CRC when they exhibit significant syndrome-like obstruction or intestinal bleeding, consistent with high mortality and poor survival in patients with CRC^5,6. CRC is found early, and is crucial for reducing mortality when it is still small and has not spread. Currently, standard white light endoscopy widely used for CRC screening often misses precancerous development abnormalities that are small, flat and patch-like^7,8. The rate of missed diagnosis of polyp and adenoma is respectively as high as 28 percent and 20 percent⁹. In addition, some invisible flat lesions may be more aggressive than visible polyps and more likely to contain cancer than polyps¹⁰. The missed diagnosis rate of small and flat lesions is up to 25 percent¹¹. Effectively find invisibilityPolyps and flat lesions are a current problem for early cancer detection. In addition, interphase cancer occurs when CRC occurs within 5 years after colonoscopy and the incidence is increasing (Farrar et al, Clin. gastroenterol. Heastol.4: 1259-.

Advanced imaging methods are being developed to improve the performance of early CRC detection. Pigment Endoscopy uses topically applied vital dyes, Narrow Band Imaging (NBI) uses filtered light in different spectral bands to highlight mucosal changes suspected of disease (Stoffel, Cancer Prev Res 1: 507-. In these methods, contrast is produced by non-specific mechanisms unrelated to the biological processes that drive the progression of CRC and has shown limited effectiveness in clinical studies.

Preclinical mouse models of disease provide important tools for studying disease development mechanisms. It has been determined that mutations in the Adenomatous Polyposis Coli (APC) gene may be a key event in the development of most adenomas and CRC. The previously reported genetically engineered mouse model that mimics mutations in the human APC gene primarily forms adenomas in the small intestine (e.g., APCMin model⁵⁶Rather than in the distal colon, polyps and their in vivo progression are difficult to image using currently available small animal endoscopic tools. Hinoi et al.⁵⁷Genetically engineered mice (termed CPC: Apc mice) are described in which a somatic mutation in the Apc allele results in a truncated Apc protein and in the formation of an adenoma in the distal colon as early as 10 weeks. Others have developed the use of cancer cell implantation⁵⁸Or adenovirus activating mutation⁵⁹A mouse model of tumor growth in the distal colon and reporting the binding of cathepsin B smart probes, but surgical intervention is required to produce polyps, with subsequent response to injury potentially leading to target alteration.

Colonoscopy has been widely accepted by physicians for decades as a procedure to aid in the detection and removal of polyps. However, conventional White Light (WL) endoscopy has difficulty in visualizing small, flat colorectal lesions. To improve the ability of endoscopes to detect and characterize colorectal lesions, a variety of endoscopic imaging techniques have been developed. The combination of molecularly targeted fluorescent reagents and broad area techniques has shown encouraging results in the detection of precancerous lesions of CRC. Studies have identified several clinical and pathological biomarkers associated with CRC prognosis. As a tyrosine kinase receptor, cMet (mesenchymal-epithelial transformation factor) is activated by hepatocyte growth factor, regulating a variety of biological processes such as cell proliferation, spreading and survival.

cMet, a member of proto-oncogenic transmembrane tyrosine kinases, is widely expressed in epithelial and endothelial cells¹⁴. cMet is expressed on the surface of normal epithelial cells of the digestive tract and is highly overexpressed in CRC. The 190kD cMet heterodimer consists of two subunits linked by disulfide bonds, including an extracellular 50kD α -chain and a transmembrane 145kD β -chain. Binding of cMet to its ligand, Hepatocyte Growth Factor (HGF), triggers cMet dimerization and autophosphorylation, which in turn phosphorylates and activates downstream mitogen-activated protein kinase (MAPK), phosphatidylinositol 3-kinase (PI3K) and Signal Transducer and Activator of Transcription (STAT) signaling pathways¹⁵. The pathway plays an important role in tumor growth, invasion, angiogenesis and metastasis¹⁶. cMet is crucial for cell proliferation, mitosis, morphogenesis and angiogenesis¹⁶. Increased cMet levels have been detected in many cancers, such as colorectal, pancreatic, gastric, hepatocellular, and breast cancers, as well as many sarcomas^17-19Making cMet an important target for anti-tumor therapy.

Endoscopic imaging using an exogenous fluorescently labeled probe can produce imaging results that provide precise localization of tumor lesions, with fluorescence providing improved contrast. Diagnostic molecules that have been used as targeting agents to date include antibodies and antibody fragments to detect precancerous and malignant lesions of various types of cancer. However, the use of antibodies and antibody fragments is limited by immunogenicity, production costs and long plasma half-life. Small molecules, RNA aptamers, and activatable probes are also used. Peptides represent a newer class of imaging agents, compatible with clinical use in the digestive tract, particularly for topical administration. Some monoclonal antibodies have been developed to target cMet fluorescenceOptical imaging agents^22,23. As mentioned above, such agents have a relatively high molecular weight and large size, which limits their ability to penetrate tissue, increases their immunogenicity, and shortens their circulating half-life.

Phage display is a powerful combinatorial technique for peptide discovery, using recombinant DNA techniques to generate complex peptide libraries, typically expressing up to 10⁷-10⁹A unique sequence that binds to a cell surface antigen. The DNA of the candidate phage can be recovered and sequenced, elucidating the positive binding peptides that can then be made synthetically. Phage display Barrett's esophagus was determined using the commercial NEB M13 phage system⁶⁰And human colon dysplasia⁶¹A peptide conjugate of high degree of dysplasia. The T7 system has proved to be effective in vivo screening experiments and can identify the islet vasculature⁶²Mammary gland vascular system⁶³Bladder tumor cell⁶⁴And liver tissue⁶⁵A unique peptide. Screening using intact tissue provides additional relevant cellular targets while taking into account subtle features in the tissue microenvironment that may affect binding.

Recent advances in vitro organoid culture technology have opened a new window for the development of new models for human cancer research. Lgr5+ stem cell-derived 'mini-gut (mini-gut)' organoids phenotypically replicate the epithelium of intestinal crypts and villi³⁰It is suggested that organoids may exhibit self-organizing ability to phenotypically replicate the fundamental aspect of the organ from which they are derived. Organoids can be derived from healthy and tumorous tissues with a high efficiency of organoid in situ xenograft procedures³¹The progress made possible the development of more physiological preclinical cancer models for early cancer detection.

Thus, there remains a need in the art for improved animal models of CRC and new products and methods for early detection of dysplasia. New products and methods for early detection would have important clinical applications to improve the survival of CRC and reduce healthcare costs.

Disclosure of Invention

Transformed cells and tissues express molecular changes prior to gross morphological changes, providing an opportunity for early detection of cancer. Peptides that bind to precancerous colorectal lesions have the potential to direct tissue biopsy of "invisible" lesions under an endoscope, and combinatorial phage display screening can be used to identify and isolate such peptides. Peptides have advantages in vivo in the gastrointestinal tract because they can be delivered locally to identify early molecular changes at the surface of epithelial cells located on the most superficial mucosa from which cancer originates. In addition, they can exhibit rapid binding kinetics and diffuse into diseased mucosa. In addition, smaller peptides reduce the chance of non-specific interactions, thereby reducing background problems found in larger targeting molecules such as proteins (e.g., antibodies), antibody fragments, and even peptides on the order of about 25 or more amino acids. Peptides that are relatively small, i.e., no more than 20 amino acids, are smaller in size and lower in molecular weight than these other targeting molecules. These characteristics help overcome many of the challenges of probe delivery, including irregular microvasculature, heterogeneous uptake and transport barriers. Improved diffusion and extravasation through leaky vessels can also result in higher concentrations and deeper penetration of the relatively smaller peptides of the present disclosure relative to these other targeting molecules. In addition, the peptides of the present disclosure have relatively low immunogenic potential. The peptides of the present disclosure are also suitable for administration to humans by a variety of routes, including rectal delivery, preferably intravenous delivery.

The data disclosed herein establish the ability of a cMet targeting peptide, such as the cMet targeting peptide QQTNWSL (SEQ ID NO:1), to detect precancerous colon lesions in vivo in a patient-derived organoid mouse model. In some exemplary embodiments, the cMet targeting peptide QQTNWSL (SEQ ID NO:1) is linked to a linker, e.g., the GGGSK linker of SEQ ID NO:2, which in turn is linked to and thereby labeled with the fluorophore cy5.5 (hereinafter referred to as QQT x-cy5.5). The data support the disclosure of such peptides, including the QQT x-cy5.5 peptide, as reagents capable of detecting pre-cancerous developmental abnormalities in an efficient and convenient manner.

The combination of molecular imaging tools with cMet-targeted fluorescent peptides (overexpressed in precancerous CRC dysplasia) is expected to improve diagnostic efficacy. Disclosed herein is a 7-amino acid peptide conjugated to a Near Infrared (NIR) fluorescent cyanine dye that specifically binds to cMet. In vitro cMet high/low expressing cell lines showed binding to cMet and the specificity of the peptide for cMet was verified in knock-down and competition studies. The disclosed peptides exhibit high binding affinity of 57nM with a time constant of 1.6 minutes, supporting rapid binding for topical application. The peptide was also shown to bind to human adenomas/SSA organoids and spontaneous colon adenomas expressing high levels of cMet in vivo. Specific uptake in human adenomas/SSA organoids and spontaneous adenomas shows the feasibility of using this peptide for real-time in vivo imaging. Immunofluorescence studies of human proximal colon specimens further demonstrate that the peptides can be used endoscopically to detect precancerous lesions and guide tissue biopsies.

As an exemplary colon dysplasia targeting peptide according to the present disclosure, the QQT-cy 5.5 peptide is a short amino acid protein fragment that functions as a targeting ligand with high specificity for cMet, a cell surface target that plays a key role in many biological processes. Peptides are expected to be used in clinical transformations to detect imaging biomarkers that are upregulated in colorectal and other cancers. They are highly diverse in nature and can be designed to bind a wide range of cell surface targets with high specificity and affinity on the nanomolar scale. By topical application, the peptides can be delivered efficiently to the mucosal surfaces of the digestive tract at high concentrations to maximize target interactions and achieve rapid binding with minimal risk of toxicity. The probe platform can flexibly label a plurality of fluorophores for multiple imaging, and has low large-scale manufacturing cost. Peptides also have low immunogenic potential allowing for repeated use. These characteristics of peptides are well suited for clinical applications in high volume surgery, such as colonoscopy.

In one aspect, the present disclosure provides a polypeptide comprising SEQ ID NO: 1. In some embodiments, the peptide is derivatized, e.g., by attachment to a linker. In some embodiments, the linker is comprised in SEQ ID NO:2 (GGGSK). In some embodiments, the derivatized peptide is labeled, e.g., with a fluorescent label. In some embodiments, the label is FITC, Cy5.5, Cy7, Li-Cor, radiolabel, biotin, luciferase, 1,8-ANS (1-anilinonaphthalene-8-sulfonic acid), 1-anilinonaphthalene-8-sulfonic acid (1,8-ANS), 5- (and-6) -carboxy-2 ',7' -dichlorofluorescein, pH9.0, 5-FAM pH9.0, 5-ROX (5-carboxy-X-rhodamine, triethylammonium salt), 5-ROX pH7.0, 5-TAMRA pH7.0, 5-TAMRA-MeOH, 6JOE, 6, 8-difluoro-7-hydroxy-4-methylcoumarin, 6-carboxyrhodamine 6G, pH7.0, 6-carboxyrhodamine 6G, hydrochloride, 6-HEX, SE pH9.0, 6-TET, SE pH9.0, 7-amino-4-methylcoumarin pH7.0, 7-hydroxy-4-methylcoumarin pH9.0, Alexa 350, Alexa 405, Alexa 430, Alexa 488, Alexa 532, Alexa 546, Alexa 555, Alexa 568, Alexa 594, Alexa 647, Alexa 660, Alexa 680, Alexa 700, Alexa Fluor 430 antibody conjugate pH 7.2, Alexa Fluor 488 antibody conjugate pH 8.0, Alexa Fluor 488 hydrazide-water, Alexa Fluor 532 antibody conjugate pH 7.2, Alexa Fluor 555 antibody conjugate pH 7.2, Alexa Fluor antibody conjugate pH 568, Alexa Fluor 610R-TEX, Alexa Fluor streptavidin conjugate pH 7.2, Alexa Fluor antibody conjugate pH 7.2, Alexa Fluor antibody conjugate 7.2, Alexa, Alexa Fluor 647R-phycoerythrin streptavidin pH 7.2, Alexa Fluor 660 antibody conjugate pH 7.2, Alexa Fluor 680 antibody conjugate pH 7.2, Alexa Fluor 700 antibody conjugate pH 7.2, allophycocyanin pH 7.5, AMCA conjugate, aminocoumarin, APC (allophycocyanin), Atto 647, BCECF pH 5.5, BCECF pH9.0, BFP (blue fluorescent protein), calcein pH9.0, calcein, calrubin Ca2+, calcogeen Ca2+, calorange Ca2+, carboxynaphthofluorescein pH 10.0, cascade blue pH7.0, cascade yellow antibody conjugate pH 8.0, CFDA, CFP (cyan fluorescent protein), CI-NERF pH 2.5, RF-NERF 6. pH 0, crystal blue pH7.0, Cy 3. BSA, Cy5, CyQUANT GR-DNA, Dansyl Cadaverine (Dansyl cadeverine), Dansyl Cadaverine, MeOH, DAPI-DNA, Dapoxyl (2-aminoethyl) sulfonamide, DDAO pH9.0, Di-8 ANEPPS, Di-8-ANEPPS-lipid, DiI, DiO, DM-NERF pH 4.0, DM-NERF pH7.0, DsRed, DTAF, dTomato, eFP (enhanced cyan fluorescent protein), eGFP (enhanced green fluorescent protein), eosinRed antibody conjugate pH 8.0, erythrosine-5-isothiocyanate pH9.0, eYFP (enhanced yellow fluorescent protein), FDA, FITC antibody conjugate pH 8.0, FluAsH, Fluo-3 Ca2⁺Fluo-4, Fluor-Ruby, fluorescein 0.1M NaOH, fluorescein antibody conjugate pH 8.0, fluorescein dextran pH 8.0, fluorescein pH9.0, Fluoro-Emerald, FM 1-43 lipids, FM 4-64, 2% CHAPS, Fura Red Ca2⁺Fura Red, high Ca, Fura Red, low Ca, Fura-2 Ca2+, Fura-2, GFP (S65T), HcRed, Indo-1Ca2⁺Indo-1, Ca-free, Indo-1, Ca-saturated, JC-1pH 8.2, lissamine rhodamine, fluorescein, CH, magnesium green Mg2+, magnesium orange, Marina Blue, mBanana, mCherry, mHoneyde, mOrange, mGlum, mRFP, mStrawberry, mTangerine, NBD-X, NBD-X, MeOH, NeuroTrace 500/525, green fluorescent Nile-stained RNA, Nile (Nile) Blue, Nile Red, Nissl, Oregon (Oregon) green 488, Oregon green 488 antibody conjugate pH 8.0, Oregon green 514 antibody conjugate pH 8.0, Rhone (Pacific) Blue, Pacific Blue antibody conjugate pH 8.0, phycoerythrin, R-7.7, Haloxyrin protein conjugate, AsuRed-362.35, Asufind 2-Ca-362.35, Rhamnion⁺Rhodamine, rhodamine 110pH

7.0, rhodamine 123, MeOH, rhodamine Green, rhodamine Phalludin pH7.0, rhodamine Red-X antibody conjugate pH 8.0, rhodamine Green pH7.0, Rhodol Green antibody conjugate pH 8.0, sapphire, SBFI-Na⁺Sodium hyaluronate Na⁺Sulfonylrhodamine 101, tetramethylrhodamine antibody conjugate pH 8.0, tetramethylrhodamine dextran pH7.0, Texas Red-X antibody conjugate pH 7.2,¹¹C、¹³N、¹⁵O、¹⁸F、³²P、⁵²Fe、⁶²Cu、⁶⁴Cu、⁶⁷Cu、⁶⁷Ga、⁶⁸Ga、⁸⁶Y、⁸⁹Zr、⁹⁰Y、⁹⁴mTc、⁹⁴Tc、⁹⁵Tc、⁹⁹mTc、¹⁰³Pd、¹⁰⁵Rh、¹⁰⁹Pd、¹¹¹Ag、¹¹¹In、¹²³I、¹²⁴I、¹²⁵I、¹³¹I、¹⁴⁰La、¹⁴⁹Pm、¹⁵³Sm、^154-159Gd、¹⁶⁵Dy、¹⁶⁶Dy、¹⁶⁶Ho、¹⁶⁹Yb、¹⁷⁵Yb、¹⁷⁵Lu、¹⁷⁷Lu、¹⁸⁶Re、¹⁸⁸Re、¹⁹²Ir、¹⁹⁸Au、¹⁹⁹Au or²¹²Bi。

In some embodiments of the peptides according to the present disclosure, the peptides are labeled with a fluorescent marker that emits in the near infrared range of the electromagnetic spectrum. In some embodiments, the fluorescent label is FITC or a cyanine dye, such as a Cy5.5 or Cy7 dye. In some embodiments, the peptide consists of SEQ ID NO: 1.

Another aspect according to the present disclosure relates to a method of detecting intestinal neoplasia comprising: (a) mixing intestinal tissue with

1, labeled peptide of a sequence shown in SEQ ID NO; (b) measuring binding of the labeled peptide to intestinal tissue; and (c) detecting intestinal neoplasia based on the measurement of binding. In some embodiments, the intestinal tissue is colorectal tissue. In some embodiments, the colorectal tissue is colon tissue. In some embodiments, the intestinal neoplasia is a precancerous lesion. In some embodiments, the intestinal neoplasia is a cancer, e.g., colorectal cancer. In some embodiments, intestinal tissue that binds the labeled peptide is not discernible as polyps by endoscopy. In some embodiments, the intestinal tissue is a polyp. In some embodiments, the binding occurs in vivo. Some embodiments of the method further comprise in vivo fluorescence imaging. In some of these embodiments, fluorescence imaging is obtained using a wide area endoscope.

As described above, the present disclosure provides peptides that bind to cMet presented on dysplastic and/or cancerous colon cells. An example of a peptide provided is the QQT-cy5.5 peptide, i.e. the peptide of SEQ ID NO: 1.

The present disclosure also provides reagents comprising peptides according to the present disclosure. In some embodiments, the reagent comprises a detectable label attached to a peptide according to the present disclosure. The detectable label may be detected, for example, by microscopy including fluorescence microscopy, ultrasound, PET, SPECT or magnetic resonance imaging. In one embodiment, the label detectable by microscopy is a member of the cyanine dye family, Fluorescein Isothiocyanate (FITC), 7-diethylaminocoumarin-3-carboxylic acid, CF-633 or 5-carboxytetramethylrhodamine. An exemplary cyanine dye is Cy5.5.

In some embodiments, the detectable label is linked to the peptide according to the present disclosure by a peptide linker. The terminal amino acid of the linker may be a lysine, such as that in the exemplary linker GGGSK (SEQ ID NO:2), as indicated above. In certain aspects, the linker is an Ahx linker, i.e., an amino-terminal linker comprising 6-aminocaproic acid.

In other embodiments, the agent comprises a therapeutic moiety linked to a peptide according to the present disclosure. The therapeutic moiety may be a chemopreventive or chemotherapeutic agent. In certain aspects, the therapeutic moiety is an anti-cancer agent, such as a potent cytotoxin with selective activity in rapidly dividing cells. Such cytotoxins include several groups of chemotherapeutic agents, such as auristatins, maytansine and calicheamicins, as well as duocarmycins and pyrrolobenzodiazepines

(PBD) dimers, all of which induce DNA damage in target cells such as tumor cells of the colon. Exemplary auristatins are monomethyl auristatin e (mmae) and monomethyl auristatin f (mmaf). The present disclosure contemplates maytansinoids and derivatives thereof, such as maytansinoids (maytansinoids). The advantageous properties of using the disclosed peptides as targeting agents also allow earlier generation cytotoxic agents to be effectively used as anti-cancer agents while limiting toxicity to acceptable levels. These older cytotoxic agents include, but are not limited to, vinca alkaloids, anthracyclines, gleevec, paclitaxel, camptothecin, doxorubicin, methotrexate, 5-fluorouracil, chlorambucil, and any anticancer agent known in the art. In a related aspect, the present disclosure provides a treatment portionIt is an anti-inflammatory agent, such as an NSAID, for example celecoxib.

In yet another aspect, the invention provides a composition comprising an agent of the invention and a pharmaceutically acceptable excipient.

In another aspect, the present disclosure provides a method of determining the effectiveness of a treatment for colon cancer and/or cancer metastasis or cancer recurrence in a patient, the method comprising the steps of: administering an agent comprising a peptide according to the present disclosure linked to a detectable label to the colon of the patient, visualizing a first amount of cells labeled with the agent, and comparing the first amount to a previously visualized second amount of cells labeled with the agent, wherein a decrease in the first amount of cells relative to the previously visualized second amount of labeled cells is indicative of an effective treatment. In some embodiments, a 5% reduction indicates effective treatment. In other embodiments, a reduction of about 10%, about 15%, about 20%, about 25%, about 30%, about 35%, about 40%, about 45%, about 50%, about 55%, about 60%, about 65%, about 70%, about 75%, about 80%, about 85%, about 90%, about 95% or more indicates effective treatment. In some embodiments, the method further comprises obtaining a biopsy of the cells labeled with the agent.

In another aspect, the invention provides a method for delivering a therapeutic agent to dysplastic colon cells in a patient, comprising the step of administering to the patient an agent comprising a peptide according to the invention linked to a therapeutic moiety.

In yet another aspect, the present disclosure provides a method for delivering a therapeutic agent to colon cells of a patient comprising the step of administering to the patient an agent comprising a peptide according to the present invention linked to a therapeutic moiety.

In yet another aspect, the present invention provides a kit for administering a composition according to the present disclosure to a patient in need thereof, wherein the kit comprises a composition according to the present disclosure, instructions for using the composition, and a device for administering the composition to a patient.

Other features and advantages of the present disclosure will be better understood by reference to the following detailed description, including the drawings and examples.

Drawings

Figure 1 cMet specific peptides show a) an exemplary target peptide sequence QQTNWSL (SEQ ID NO:1) and B) a scrambled control peptide sequence TLQWNQS (SEQ ID NO:3) the biochemical structure of (1). The GGGSK linker (SEQ ID NO:2) separates the Cy5.5 fluorophore from the amino acid sequence of the labeled peptide to prevent steric hindrance. C and D) three-dimensional models show the differences of biochemical structures. E) Peak absorbance and F) maximum fluorescence emission occurs at λ_abs675nm and λ_em＝710nm。

Figure 2 in vitro validation using cMet knockdown. A) QQT x-cy5.5 peptide (red) and B) AF488 labeled anti-cMet antibody (green) showed strong binding to the surface of human HT29 colorectal cancer cells transfected with siCL non-targeting siRNA (control) using confocal microscopy (arrow). C) The control peptide TLQ-cy 5.5 (red) showed minimal binding. D) Peptide and E) the fluorescence intensity of the antibody decreased with HT29 knockdown of the cells transfected with the sicMet targeting siRNA. F) TLQ-cy 5.5 (red) had little binding. G) QQT-cy 5.5 and anti-cMet-AF 488 showed a significant decrease in intensity, with 2.9-fold and 4.1-fold knockdown of cMet, respectively. TLQ-cy 5.5 showed no significant decrease (0.96-fold, P-0.52). The intensity of QQT-cy5.5 was significantly higher compared to TLQ-cy5.5 (8.1 fold). With respect to the log transformed data, a two-way ANOVA model was fitted to the terms of 6 conditions and 6 replicate slices. The measurements are the average of 5 cells randomly selected on 6 slices per condition. H) Western blot showed cMet expression under each condition.

Figure 3 cMet specific peptide a) unlabelled QQT was added to compete with QQT-cy 5.5 for binding to HT29 cells, resulting in a significant decrease in fluorescence intensity in a concentration-dependent manner. TLQ did not change significantly. With respect to log-transformed data, a two-way ANOVA model was fitted to the concentrations of labeled peptides, unlabeled peptides, and their interacting terms. The measurements are the average of 5 cells randomly selected on 3 slices per condition. B) The binding of QQT × cy5.5 (red) and anti-cMet-AF 488 (green) co-localized to the surface of HT29 cells (arrow), ρ ═ 0.73. C) Measurement of the apparent dissociation constant k of QQT-Cy5.5 binding to HT29 cells_d＝57nM，R²0.98. D) Measurement of the apparent binding time constant k of QQT-Cy5.5 to HT29 cells 0.62min^-1(1.6min)，R²0.97. These results are representative of 3 independent experiments.

FIG. 4. Effect of peptides on cell signaling and growth. Peptide binding did not affect cell signaling. (A) From western blot, HGF (25ng/mL) induced phosphorylation of cMet and downstream AKT and Erk1/2 in HT29 cells after incubation for 10, 30 and 120min (i.e., min). HGF (100ng/mL) was used as a positive control, and none (none) was used as a negative control. Incubation with 5 or 100 μ M QQT-cy 5.5 showed no effect on p-cMet (phosphorylation activity of cMet) expression or downstream AKT and Erk1/2 signaling. Beta-tubulin was used as a loading control. The set of strips was cut from different portions of the same gel. The alamar blue test showed that after 48 hours, the growth of (B) HT29 cells was increased but not (C) CCD841 cells after the addition of HGF. No change was observed in QQT-Cy5.5 at either 5 or 100. mu.M. An ANOVA model with 4 groups of terms was fitted to the log transformed data with 3 independent experiments.

FIG. 5. in vivo endoscopic imaging of a human colon organoid CPC; in vivo imaging in Apc mice. (A) The white light image showed no visible lesions (flat). (B) NIR fluorescence images after intrarectal administration of QQT-cy 5.5 showed an increase in intensity of the flat lesions (arrows). (C) Co-registered reflectance images are obtained from the same lesion. (D) Fluorescence images collected using TLQ x-cy 5.5 (control) showed minimal signal. (E) A white light image of the colon shows the presence of polyps (arrows). (F) QQT-cy 5.5 showed an increase in fluorescence intensity from polyps (arrow). (G) Co-registered reflectance images of polyps are collected. (H) TLQ-cy 5.5 showed minimal signal. (I) The ratio of fluorescence and reflectance images of the flat lesion in (a) is shown. (J) The fluorescence (red), reflectance (green) and ratio (blue) intensity of the dashed line in (I) are shown. (K) In 8 mice, QQT-cy 5.5 showed significantly higher mean (± SD) T/B ratios of flat lesions (7) and polyps (8) compared to adjacent normal mucosa by paired T-test on log transformed data, varying by 1.7 and 2.1 fold, respectively. (L) white light image of the resected colon shows many polyps (arrows) on the exposed mucosal surface. (M) fluorescence images collected in vitro show an increase in polyp intensity after topical application of QQT x-cy 5.5. (N) merging the images. (O) in n-5 mice, the mean fluorescence intensity from adenomas was 2.6 times higher than that from normal-looking adjacent normal mucosa by paired t-test of log-transformed data. Immunohistochemistry (IHC) showed higher expression of cMet for (P) dysplasia compared to (Q) normal.

FIG. 6 in vitro validation using human colon specimens. The combined images showed by confocal microscopy that QQT x-cy 5.5 (red) and anti-cMet-AF 488 (green) bound to co-localization of a) adenoma, B) SSA, C) Hyperplastic Polyps (HP) and D) normal mucosa. Pearson correlation coefficients ρ of 0.82, 0.79, 0.86 and 0.75 were measured, respectively. E) Adenoma, F) SSA, G) HP, and H) immunohistochemistry of normal colonic mucosa (IHC) support cMet expression. An ANOVA model with 4 groups of terms was used on log transformed data with 3 repeated intensity measurements per sample, showing I) adenoma, J) SSA, K) HP, and L) representative histology of normal colonic mucosa (H)&E) (ii) a M) adenomas (n ═ 21) mean fluorescence intensities were significantly higher than normal (n ═ 10) and HP (n ═ 7), with 3.0 and 2.4 fold changes, respectively. For SSA (n ═ 13), the mean fluorescence intensity was also significantly higher than normal and HP, with 2.8 and 2.2 fold changes, respectively. The measurements were 20X 20 μm in size per slide²Of 3 regions of interest (ROI).

FIG. 7 quantitative immunofluorescence results for human colon specimens. A) Mean fluorescence intensity of adenomas (n ═ 21) was significantly higher than HP (n ═ 7) and normal cells (n ═ 10), with two samples t-test giving 2.4-fold and 3.0-fold changes, respectively. The results for SSA (n ═ 13) were also significantly higher than for HP and normal cells, with 2.2 and 2.8 fold changes, respectively. The measurements are the average of 3 regions of interest (ROIs) of 25 x 25 pixels in size per slide. The ANOVA model was fitted to 4 groups of terms with 3 replicate intensity measurements per sample. B) ROC curve shows 86% sensitivity and 88% specificity, Area Under Curve (AUC) 0.94 for differentiating adenomas from normal cells and HP, and C) 92% sensitivity and 88% specificity, AUC 0.95 for differentiating SSA from normal cells and HP.

Figure 8. QQT x-cy5.5 peptide (red) and AF 568-labeled anti-cMet antibody (yellow) bound to adenoma human colon organoids under confocal microscopy. Human specific cytokeratin staining of organoids indicates successful transplantation. H & E staining of organoid xenografts. Statistics of in vivo imaging of QQT-cy 5.5 and control TLQ-cy 5.5 in human adenomatous organoid xenografts. The fluorescence intensity of QQT was 3.2 times higher than TLQ.

FIG. 9 Mass Spectrometry analysis of Cy5.5 labeled peptides. Experimental mass to charge (m/z) ratios of a) qt-cy 5.5 and B) TLQ-cy 5.5 were found to be 1827.67, indicating agreement with the expected values.

FIG. 10 peptide validation of human colorectal cancer cells in vitro. Under confocal microscopy, a) qt-cy 5.5 (red) and B anti-cMet-AF 488 (green) showed strong binding to the surface of HT29 cells (cMet +) (arrows). C) The control peptide TLQ-cy 5.5 (red) showed minimal binding. In contrast, a decrease in signal was observed with the D) peptide and E) SW480 cell antibody (cMet-). F) TLQ-cy 5.5 (red) had little binding. G) The quantification results showed that HT29 showed significantly higher mean intensities of qt-cy 5.5 and anti-cMet-AF 488 compared to SW480 cells, with 2.1-fold and 4.3-fold changes, respectively, and 4.5 × 10 for P ═ h^-10And 3.2X 10^-17. TLQ-cy 5.5 showed no significant decrease (0.85 fold change, P ═ 0.07). The intensity of QQT-cy 5.5 for HT29 was significantly greater than that of HT29 cells for TLQ-cy 5.5(7.5 fold change, P ═ 4.5 × 10)^-21). With respect to the log transformed data, a two-way ANOVA model was fitted to the terms of 6 conditions and 6 replicate slices. The measurements are the average of 5 cells randomly selected on 6 slices per condition. H) Western blot shows cMet expression level per cell.

FIG. 11 peptide validation of mouse cells in vitro. Under confocal microscopy, a) qt-cy 5.5 (red) and B anti-cMet-AF 488 (green) showed strong binding to the surface of S114 cells (cMet +) (arrows). C) The control peptide TLQ-cy 5.5 (red) showed minimal binding. In contrast, a reduced signal was observed with the D) peptide and E) NIH3T3 cell antibody (cMet-). F) TLQ-cy 5.5 (red) had little binding. G) The quantification results showed that the average intensity of qt-cy 5.5 and anti-cMet-AF 488 was significantly higher for S114 compared to NIH3T3 cells, with 2.4-fold and 6.7-fold changes, respectively, and 1.7 × 10 for P^-16And 4.0X 10^-26. TLQ-cy 5.5 showed no significant decrease (0.72 fold change, P ═ 8.2 × 10^-7). The intensity of QQT-cy 5.5 for S114 was significantly greater than that of S114 cells for TLQ-cy 5.5(7.0 fold change, P ═ 2.6 × 10)^-26). With respect to the log transformed data, a two-way ANOVA model was fitted to the terms of 6 conditions and 6 replicate slices. The measurements are the average of 5 cells randomly selected on 6 slices per condition. H) Western blot shows cMet expression level per cell. I) The mean intensities of QQT x-cy 5.5 and anti-cMet-AF 488 and S114 were significantly higher than with NIH3T3 cells, with 2.4 and 6.7 fold changes, respectively. TLQ-cy 5.5 showed no significant increase. The average intensity of QQT-cy 5.5 was significantly higher than TLQ-cy 5.5 with a 7.0 fold change. The difference between S114 and NIH3T3 of QQT x-cy5.5 was significantly higher than that of TQL x-cy5.5 (P ═ 1.3 × 10)^-8). An ANOVA model was fitted to the log transformed data with terms of 6 conditions. Each condition had 6 replicate slides, each slide measuring 10 cells.

FIG. 12. CPC; in vivo imaging in Apc mice. A) The white light image shows no macroscopic lesions (polyps), consistent with the presence of flat lesions. B) NIR fluorescence images of QQT-cy 5.5 showed the presence of flat lesions (arrows). C) Fluorescence registered reflectance images are obtained. D) Images of the same area as TLQ x-cy 5.5 (control) showed minimal signal. E) White light endoscopic images of the colon show the presence of spontaneous polyps (arrows) and normal appearing mucosa. F) NIR fluorescence images after topical application of QQT-cy 5.5 show an increase in polyp intensity (arrow). G) Fluorescence registered reflectance images are obtained. H) The TLQ x-cy 5.5 image shows the minimum signal. I) The ratio of fluorescence and reflectance images from flat lesions is shown in figure S4A. J) The fluorescence (red), reflectance (green) and ratio (blue) values of the dashed lines in fig. S4I. K) In 8 mice, QQT-cy 5.5 showed a higher mean (± SD) T: B ratio from polyps (8) and flat lesions (7) than from adjacent normal mucosa, 3.85 ± 1.1 and 3.76 ± 0.67, respectively, with P ═ 1.1 × 10 in paired T-tests^-3And P ═ 7.8 × 10^-3. L) polyps and M) histology of flat lesions with adjacent normal mucosa (H)&E) Showing signs of low grade dysplasia.

FIG. 13.CPC; macroscopic validation of cMet expression in the colon of Apc mice. A) The white light image shows numerous dysplastic polyps (arrows) on the exposed mucosal surface of the excised mouse colon. B) The fluorescence images show an increase in the intensity of polyps after topical application of QQT x-cy 5.5. C) The merged image is displayed. D) In 5 mice, 10 dysplastic regions had a 2.7-fold higher mean fluorescence intensity than the uninvolved peripheral normal mucosa, and P of paired t-test was 1.6 × 10^-5. Immunohistochemistry (IHC) supported cMet overexpression in E) dysplasia and F) normal mucosa. (L) white light image of the resected colon shows many polyps (arrows) on the exposed mucosal surface. (M) fluorescence images collected in vitro show an increase in polyp intensity after topical application of QQT x-cy 5.5. (N) merging the images. (O) in n-5 mice, the mean fluorescence intensity from adenomas was 2.6 times higher than that from normal-looking adjacent normal mucosa by paired t-test of log-transformed data. Immunohistochemistry (IHC) showed higher expression of cMet for (P) dysplasia compared to (Q) normal.

FIG. 14. CPC; in vivo imaging in Apc mice. A) White light endoscopic images of the colon show the presence of spontaneous polyps (arrows) and normal appearing mucosa. B) NIR fluorescence images after topical application of QQT-cy 5.5 show an increase in polyp intensity (arrow). C) Images of the same area as TLQ x-cy 5.5 (control) showed minimal signal. D) The white light image shows no macroscopic lesions (polyps). E) NIR fluorescence images of QQT-cy 5.5 showed the presence of flat lesions (arrows). F) The TLQ x-cy 5.5 image shows the minimum signal. G) In 8 mice, QQT-cy 5.5 showed a higher mean (± SD) T: B ratio from polyps (8) and flat lesions (7) than from adjacent normal mucosa, 3.85 ± 1.1 and 3.76 ± 0.67, respectively, with P ═ 1.1 × 10 in paired T-tests^-3And P ═ 7.8 × 10^-3. H) Polyps and I) histology of flat lesions with adjacent normal mucosa (H)&E) Showing signs of low grade dysplasia.

FIG. 15. CPC; macroscopic validation of cMet expression in the colon of Apc mice. Under confocal microscopy, the binding of a) qt x-cy5.5 peptide (red) and B) AF 488-labeled anti-cMet antibody (green) co-localized to the surface of dysplastic colon cells in tubular adenomas (arrows). C) In the mergingOn the image, Pearson correlation coefficient □ was measured to be 0.78. D-F) a reduction in the signal of normal mucosa was observed. G. I) mean (± SD) fluorescence intensity of adenomas (n ═ 30) was significantly higher than normal (n ═ 30), 6.2 ± 0.17 and 4.9 ± 0.25, respectively, and P ═ 2.4 × 10 by paired t-test on log-transformed data^-4. H) The ROC curve shows 93% sensitivity and 87% specificity, AUC 0.96, to distinguish dysplasia from normality. J. K) shows histology (H)&E)。

FIG. 16 in vivo imaging of normal and SSA human colon organoids. White light images show patient-derived normal mucosa (arrow) a) and patient-derived SSA (arrow) E) implanted into the colon of NOD/SCID mice. Fluorescence images were collected after topical application of QQT-cy 5.5 and showed strong signals from SSA organoids (arrow) F) while intensities from normal organoids (arrow) B) were minimal. C. G) shows the registered reflectance image. After 3 days, imaging with TLQ x-cy 5.5 (control) from the same normal D) and SSA H) organoids showed almost no signal (arrows). I) For in vivo imaging, mean fluorescence intensity was found to be significantly higher for SSA organoids than for normal organoids. H & E staining shows normal J) and SSA M) organoids histology of the transplant. Human specific hcytokeratin staining revealed normal K) and SSA N) organoid transplantation success. cMet and QQT-cy 5.5 co-localise IF on normal L) and adenoma O) organoids.

FIG. 17 peptide characterization. A) Using confocal microscopy, the binding of QQT x-cy 5.5 to HT29 cells showed no change with the addition of HGF. B) Binding of QQT to mouse cMet-ECD compared to TLQ, a strong band was seen from the pull-down analysis. Key words: a total of-20 μ g mouse cMet-ECD without EHS beads; peptide-free EHS beads; QQT-a target peptide immobilized on EHS beads; TLQ-control peptide immobilized on EHS beads.

FIG. 18 Western blot. For a) cMet knockdown of siRNA in HT29 cells (fig. 2H), B) cMet expression in HT29 and SW480 cells (fig. 10H), C) cMet expression in S114 and NIH3T3 cells (fig. 11H), and D-H) downstream cMet signaling was detected in HT29 cells (fig. 4) treated with HGF (25ng/mL) or qt-cy 5.5(5 or 10 μ M), I) binding of qt to mouse cMet-ECD (fig. 17), showing an unclipped gel. All blots were from the same gel, but developed on different films.

FIG. 19 in vivo endoscopic imaging of human colon organoids shows A) white light and B) reflectance images of adenomas implanted in the colon of NOD/SCID mice. Fluorescence images collected after topical application of C) QQT-cy 5.5 showed strong intensity from adenomas, while D) TLQ-cy 5.5 provided minimal signal. The E) white light and F) reflectance images of SSA are shown. Fluorescence images collected using G) QQT-cy 5.5 showed strong intensity from SSA, while H) TLQ-cy 5.5 provided minimal signal. Normal I) white light and J) reflectance images are shown. Fluorescence images collected using G) QQT-cy 5.5 and H) TLQ-cy 5.5 showed minimal signal.

Detailed Description

It is expected that relatively small peptide-based fluorescent imaging probes directed to cancer biomarkers will increase visualization of precancerous lesions, with lower immunogenicity and faster clearance. Several clinical studies have shown that peptides can be used as diagnostic tools to guide tissue biopsies in the gastrointestinal tract^27,28. The relatively small size of the peptide compared to the antibody allows the peptide to more readily penetrate deep tissues with minimal immunogenicity. Peptide-based imaging probes also exhibit a high degree of diversity and labeling flexibility at affordable cost and rapid binding kinetics. These advantages make peptides highly suitable for in vivo imaging and clinical use.

The present disclosure provides a fluorescently labeled peptide specific for cMet to detect precancerous developmental abnormalities in CRC. The peptide was shown to detect precancerous colon lesions in vivo, which were flat in appearance and easily missed by colonoscopy with white light illumination. Using biopanning techniques with phage display libraries, we identified a heptapeptide that specifically binds to the extracellular domain of cMet. After labeling with the near infrared fluorescent dye, cy5.5, we administered this peptide topically to the distal colon surface of mice, which minimizes toxicity and reduces the risk of binding to unintended tissues. The peptide exhibits an excellent target background (T/B) signal ratio compared to a scrambled control peptide. The function of the peptides as probes or targeting ligands was examined in the experiments disclosed herein and the results demonstrate that peptides specific for cMet are expected to be useful for endoscopic detection of precancerous lesions and to provide guidance for biopsy localization.

Phage display technology was used to biopanning (biopan) a linear heptad library against the extracellular domain (ECD) of cMet and to identify the heptad sequence QQTNWSL (SEQ ID NO: 1). We covalently linked the C-terminus of this linear monomer (black) to the Near Infrared (NIR) fluorophore cy5.5 (red) by GGGSK (SEQ ID NO:2) linker (blue), hereafter referred to as QQT-cy 5.5. The peptide is separated from the fluorophore to minimize the effect of steric hindrance. Cy5.5 was chosen because it is less sensitive to hemoglobin absorption and tissue scattering, minimizes the effects of tissue autofluorescence, and provides maximum light penetration depth. We achieved over 95% purity for both peptides using HPLC and measured the experimental mass to charge (m/z) ratio on the mass spectrum to be 1827, consistent with the expected values. We measured the apparent dissociation constant K of peptides binding to HT29 human colorectal adenocarcinoma cells _D57 nM. In addition, we measured the apparent binding time constant k 0.622min-1(1.61 min).

Overexpression of cMet is an early event in CRC neoplasia, making detection of cMet expression levels a promising approach to identify poor pre-cancerous development of CRC^20,21. Furthermore, its location on the cell membrane allows cMet access to imaging agents, such as fluorescent targeting agents. Increased cMet levels have been reported for a variety of cancer types, particularly colorectal cancer. Various preclinical and clinical findings demonstrate that cMet is a promising target for molecular imaging, allowing for monitoring of abnormal changes in real time and in vivo.

Disclosed herein is a NIR-labeled cMet targeting peptide for targeting at Cpc; in vivo fluorescence imaging was performed in a polyp mouse model and a human organ transplant mouse model, where Apc spontaneously develops. QQTNWSL (SEQ ID NO:1) was selected for the extracellular domain of cMet by biopanning and phage display. Specific binding to cMet was verified in vitro and ex vivo using standard assays, such as competition and cell binding assays. The peptide exhibits a high binding affinity of kd 57nM, binding occurring within 2 minutes (k 0.622min-1) This is compatible with clinical use during colonoscopy. In a spontaneous mouse model of CRC, we demonstrated that this peptide is able to detect flattened and polyploid colon adenomas in vivo, which are pathologically diagnosed as low grade dysplasia. In order to more accurately simulate the real physiological functions of the human body, a human organ transplantation mouse model was developed. By in situ injection, this mouse model produced colonic polyps derived from human organs, faithfully reproducing human CRC. One of the important goals of advanced imaging techniques is to distinguish benign hyperplastic polyps from malignant lesions (e.g., jagged polyps) to avoid unnecessary cost and treatment⁴⁷. The imaging results using the organoid transplant mouse model disclosed herein indicate that the QQT x-cy5.5 fluorescently labeled peptide binds to human adenomas and SSA with minimal binding to normal organoids. This observation was further confirmed by IF staining of human proximal colon tissue of different subtypes with QQT-cy 5.5, which showed that fluorescently labeled peptides distinguished adenoma or SSA from normal and HP, with 88% sensitivity and 82% specificity, and an area under the curve (AUC) of 0.94.

Molecular imaging probe-based antibodies against cMet have been validated^48,49. Although antibodies and antibody fragments can achieve high binding affinities, they are limited in diagnostic terms due to slow binding kinetics, long half-lives, and increased background. Peptides are safer and less costly than antibodies because of their lower molecular weight. Peptides have several advantages, such as favorable pharmacokinetic and tissue distribution patterns, higher permeability, lower toxicity, lower immunogenicity, and ease of chemical modification⁵⁰. Topical administration of peptides delivers therapeutic agents directly to target tissues at high concentrations with risk of disease, to maximize binding interactions and achieve high image contrast with little risk of toxicity. This approach avoids unwanted biodistribution to other tissues of the exogenous agent as a characteristic of administration by, for example, intravenous injection.

Recently, there is increasing evidence that cMet is associated with other cell surface Receptor Tyrosine Kinases (RTKs) and cell surface proteins associated with tumor formation and progression in colorectal cancer, such as blood vesselsEndothelial Growth Factor Receptor (VEGFR)^51,52And Epidermal Growth Factor Receptor (EGFR)^53,54And (4) associating. Due to the complexity and heterogeneity of disease in a broad patient population, multiple imaging methods using multiple targets may prove beneficial^35,55。

Linker and polypeptide

As used herein, a "linker" is an amino acid sequence located at the end of a peptide of the present disclosure, which is typically uncharged. In some embodiments, the linker sequence terminates with a lysine residue. Uncharged amino acids contemplated by the present disclosure include, but are not limited to, glycine, serine, cysteine, threonine, histidine, tyrosine, asparagine, and glutamine.

In some embodiments, the presence of the linker results in at least a 1% increase in detectable binding of the agent of the present disclosure to dysplastic or cancerous colon cells as compared to detectable binding of the agent in the absence of the linker. In various aspects, the increase in detectable binding is at least 2%, at least 3%, at least 4%, at least 5%, at least 6%, at least 7%, at least 8%, at least 9%, at least 10%, at least 11%, at least 12%, at least 13%, at least 14%, at least 15%, at least 16%, at least 17%, at least 18%, at least 19%, at least 20%, at least about 25%, at least about 30%, at least about 35%, at least about 40%, at least about 45%, at least about 50%, at least about 55%, at least about 60%, at least about 65%, at least about 70%, at least about 75%, at least about 80%, at least about 85%, at least about 90%, at least about 95%, at least about 99%, at least about 2-fold, at least about 3-fold, at least about 4-fold, at least about 5-fold, at least about 6-fold, at least about 7-fold, at least about 8-fold, at least about 9-fold, at least about 10-fold, at least about 15 times, at least about 20 times, at least about 25 times, at least about 30 times, at least about 35 times, at least about 40 times, at least about 45 times, at least about 50 times, at least about 100 times, or more.

The term "peptide" refers to molecules of 2 to 50 amino acids, molecules of 3 to 20 amino acids and molecules of 6 to 15 amino acids. Peptides and linkers contemplated by the present invention may be 5 amino acids in length. In various aspects, the polypeptide or linker can be 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50 or more amino acids in length.

In various aspects, exemplary peptides are randomly generated by methods known in the art, carried in a library of polypeptides (e.g., without limitation, a phage display library), derived by protein digestion, or chemically synthesized. The peptides exemplified in the present disclosure can be obtained using phage display technology, which is an efficient combinatorial approach using recombinant DNA technology to generate complex libraries of polypeptides for selection by preferential binding to cell surface targets [ Scott et al, Science (Science), 249: 386-390(1990)]. The protein coat of bacteriophages, such as filamentous M13 or icosahedral T7, is genetically engineered to express very large amounts (greater than 10)⁹) To achieve affinity binding [ cwrla et al, "american national association of science (proc. natl. acad. sci. usa), 87: 6378-6382(1990)]. Selection is then performed by biopanning the phage library against cultured cells and tissues that overexpress the target. The DNA sequences of these candidate phages were then recovered and used to synthesize polypeptides [ Pasqualini et al, Nature 380: 364-366(1996)]. Polypeptides that preferentially bind to dysplastic mucosa are optionally labeled with a fluorescent dye, including, but not limited to FITC, Cy5.5, Cy7, and Li-Cor.

Peptides include the D and L forms either purified or as a mixture of the two forms. The present disclosure also contemplates peptides that compete with the peptides of the invention to bind to colon cells.

It will be appreciated that the peptides and linkers of the invention optionally incorporate modifications known in the art, and that the position and number of such modifications may be varied to achieve optimal results.

Detectable labels

As used herein, a "detectable marker" is any marker that can be used to identify binding of a composition of the present disclosure to intestinal tissue, such as colon tissue. Non-limiting examples of detectable labels are fluorophores, chemical tags or protein tags capable of visualizing the polypeptide. In certain aspects, visualization may be with the naked eye or with a device (e.g., without limitation, an endoscope), and may also involve alternative light or energy sources.

Fluorophores, chemical and protein tags contemplated for use in the present invention include, but are not limited to, FITC, Cy5.5, Cy7, Li-Cor, radiolabel, biotin, luciferase, 1,8-ANS (1-anilinonaphthalene-8-sulfonic acid), 1-anilinonaphthalene-8-sulfonic acid (1,8-ANS), 5- (and-6) -carboxy-2 ',7' -dichlorofluorescein pH9.0, 5-FAM pH9.0, 5-ROX (5-carboxy-X-rhodamine, triethylammonium salt), 5-ROX pH7.0, 5-TAMRA pH7.0, 5-TAA-MRA, 6JOE, 6, 8-difluoro-7-hydroxy-4-methylcoumarin pH9.0, 6-carboxyrhodamine 6G pH7.0, 6-carboxyrhodamine 6G, hydrochloride, 6-HEX, SE pH9.0, 6-TET, SE pH9.0, 7-amino-4-methylcoumarin pH7.0, 7-hydroxy-4-methylcoumarin pH9.0, Alexa 350, Alexa 405, Alexa 430, Alexa 488, Alexa 532, Alexa 546, Alexa 555, Alexa 568, Alexa 594, Alexa 647, Alexa 660, Alexa 680, Alexa 700, Alexa Fluor 430 antibody conjugate pH 7.2, Alexa Fluor 488 antibody conjugate pH 8.0, Alexa Fluor 488 hydrazide-water, Alexa Fluor 532 antibody conjugate pH 7.2, Alexa Fluor 555 antibody pH 7.2, Alexa Fluor Flora 555 conjugate pH 7.568, Alexa Fluor streptavidin conjugate pH 2.610 Alexa Fluor 647 antibody conjugate pH 7.2, Alexa Fluor 647R-phycoerythrin streptavidin pH 7.2, Alexa Fluor 660 antibody conjugate pH 7.2, Alexa Fluor 680 antibody conjugate pH 7.2, Alexa Fluor 700 antibody conjugate pH 7.2, allophycocyanin pH 7.5, AMCA conjugate, aminocoumarin, APC (allophycocyanin), Atto 647, BCECF pH 5.5, BCECF pH9.0, BFP (blue fluorescent protein), calcein pH9.0, calcein Ca2+, calcein Ca2+, calorange, calcein Ca 26 +, carboxynaphtho fluorescein pH 10.0, calcein cascade blue, cascade BSA pH7.0, cascade yellow, yellow cascade antibody pH 8.0, CFDA, CFP (cyan fluorescent protein), CFP-orange Ca2+, carboxynaphtho fluorescein pH 10.0, NECI-RF pH6.0, NECI,Cy 2, Cy 3, Cy 3.5, Cy5, CyQUANT GR-DNA, Dansyl Cadaverine (Dansyl cadeverine), Dansyl Cadaverine, MeOH, DAPI-DNA, Dapoxyl (2-aminoethyl) sulfonamide, DDAO pH9.0, Di-8 ANEPPS, Di-8-ANEPPS-lipid, DiI, DiO, DM-NERF pH 4.0, DM-NERF pH7.0, DsRed, DTAF, dTomato, eCFP (enhanced cyan fluorescent protein), eGFP (enhanced green fluorescent protein), eosin conjugate antibody pH 8.0, FDA red-5-isothiocyanate pH9.0, eYFP (enhanced yellow fluorescent protein), erythro, FITC antibody conjugate pH 8.0, FluAsH, Fluo-3 Ca2⁺Fluo-4, Fluor-Ruby, fluorescein 0.1M NaOH, fluorescein antibody conjugate pH 8.0, fluorescein dextran pH 8.0, fluorescein pH9.0, Fluoro-Emerald, FM 1-43 lipids, FM 4-64, 2% CHAPS, Fura Red Ca2⁺Fura Red, high Ca, Fura Red, low Ca, Fura-2 Ca2+, Fura-2, GFP (S65T), HcRed, Indo-1Ca2⁺Indo-1, Ca-free, Indo-1, Ca-saturated, JC-1pH 8.2, lissamine rhodamine, fluorescein, CH, magnesium green Mg2+, magnesium orange, Marina Blue, mBanana, mCherry, mHoneyde, mOrange, mGlum, mRFP, mStrawberry, mTangerine, NBD-X, NBD-X, MeOH, NeuroTrace 500/525, green fluorescent Nile-stained RNA, Nile (Nile) Blue, Nile Red, Nissl, Oregon (Oregon) green 488, Oregon green 488 antibody conjugate pH 8.0, Oregon green 514 antibody conjugate pH 8.0, Rhone (Pacific) Blue, Pacific Blue antibody conjugate pH 8.0, phycoerythrin, R-7.7, Haloxyrin protein conjugate, AsuRed-362.35, Asufind 2-Ca-362.35, Rhamnion⁺Rhodamine, rhodamine 110pH 7.0, rhodamine 123, MeOH, rhodamine green, rhodamine phalloidin (Phallodin) pH7.0, rhodamine red-X antibody conjugate pH 8.0, rhodamine green pH7.0, Rhodol green antibody conjugate pH 8.0, sapphire, SBFI-Na⁺Sodium hyaluronate Na⁺Sulfonylrhodamine 101, tetramethylrhodamine antibody conjugate pH 8.0, tetramethylrhodamine dextran pH7.0, and Texas Red-X antibody conjugate pH 7.2.

Non-limiting examples of chemical tags contemplated by the present inventionIncluding radioactive labels. For example, but not limited to, radioactive labels contemplated in the compositions and methods of the present disclosure include¹¹C、¹³N、¹⁵O、¹⁸F、³²P、⁵²Fe、⁶²Cu、⁶⁴Cu、⁶⁷Cu、⁶⁷Ga、⁶⁸Ga、⁸⁶Y、⁸⁹Zr、⁹⁰Y、⁹⁴mTc、⁹⁴Tc、⁹⁵Tc、⁹⁹mTc、¹⁰³Pd、¹⁰⁵Rh、¹⁰⁹Pd、¹¹¹Ag、¹¹¹In、¹²³I、¹²⁴I、¹²⁵I、¹³¹I、¹⁴⁰La、¹⁴⁹Pm、¹⁵³Sm、^154-159Gd、¹⁶⁵Dy、¹⁶⁶Dy、¹⁶⁶Ho、¹⁶⁹Yb、¹⁷⁵Yb、¹⁷⁵Lu、¹⁷⁷Lu、¹⁸⁶Re、¹⁸⁸Re、¹⁹²Ir、¹⁹⁸Au、¹⁹⁹Au and²¹²Bi。

one of ordinary skill in the art will appreciate that there are many such detectable labels that can be used to visualize the compositions of the present disclosure in vitro, in vivo, or ex vivo.

Therapeutic moieties

Therapeutic moieties contemplated by the present invention include, but are not limited to, polypeptides or peptides, small molecules, therapeutic agents, chemotherapeutic agents, or combinations thereof.

As used herein, the term "small molecule" refers to a compound, such as a peptidomimetic or oligonucleotide that may optionally be derivatized, or any other natural or synthetic low molecular weight organic compound.

By "low molecular weight" is meant compounds having a molecular weight of less than 1000 daltons, typically between 300 and 700 daltons. In various aspects, the low molecular weight compound is about 100, about 150, about 200, about 250, about 300, about 350, about 400, about 450, about 500, about 550, about 600, about 650, about 700, about 750, about 800, about 850, about 900, about 1000 or more daltons.

In some aspects, the therapeutic moiety is a protein therapeutic. Protein therapeutics include, but are not limited to, cellular or circulating proteins and fragments and derivatives thereof. Still other therapeutic moieties include polynucleotides including, but not limited to, polynucleotides encoding proteins, polynucleotides encoding regulatory polynucleotides, and/or self-regulatory polynucleotides. Optionally, the composition comprises a combination of compounds described herein.

In various aspects, protein therapeutics include cytokines or hematopoietic factors, including but not limited to IL-1 α, IL-1 β, IL-2, IL-3, IL-4, IL-5, IL-6, IL-11, colony stimulating factor-1 (CSF-1), M-CSF, SCF, GM-CSF, granulocyte colony stimulating factor (G-CSF), EPO, interferon- α (IFN- α), consensus interferon, IFN- β, IFN- γ, IL-7, IL-8, IL-9, IL-10, IL-12, IL-13, IL-14, IL-15, IL-16, IL-17, IL-18, Thrombopoietin (TPO), angiopoietins such as Ang-1, Ang-2, Ang-4, Ang-Y (human angiopoietin-like polypeptide), Vascular Endothelial Growth Factor (VEGF), angiogenin, bone morphogenetic protein-1, bone morphogenetic protein-2, bone morphogenetic protein-3, bone morphogenetic protein-4, bone morphogenetic protein-5, bone morphogenetic protein-6, bone morphogenetic protein-7, bone morphogenetic protein-8, bone morphogenetic protein-9, bone morphogenetic protein-10, bone morphogenetic protein-11, bone morphogenetic protein-12, bone morphogenetic protein-13, bone morphogenetic protein-14, bone morphogenetic protein-15, bone morphogenetic protein receptor IA, bone morphogenetic protein receptor IB, brain-derived neurotrophic factor, ciliary neurotrophic factor, Ciliary neurotrophic factor receptor, cytokine-induced neutrophilic chemokine 1, cytokine-induced neutrophil, chemokine 2 alpha, cytokine-induced neutrophil chemokine 2 beta, beta endothelial growth factor, endothelin 1, epidermal growth factor, epithelial-derived neutrophil attractant, fibroblast growth factor 4, fibroblast growth factor 5, fibroblast growth factor 6, fibroblast growth factor 7, fibroblast growth factor 8b, fibroblast growth factor 8c, fibroblast growth factor 9, fibroblast growth factor 10, fibroblast growth factor acidity, fibroblast growth factor basicity, glial cell line-derived neurotrophic factor receptor alpha 1, glial cell line-derived neurotrophic factor receptor alpha 2, Growth-related protein, growth-related protein alpha, growth-related protein beta, growth-related protein gamma, heparin-binding epidermal growth factor, hepatocyte growth factor receptor, insulin-like growth factor I, insulin-like growth factor receptor, insulin-like growth factor II, insulin-like growth factor binding protein, keratinocyte growth factor, leukemia inhibitory factor receptor alpha, nerve growth factor receptor, neurotrophin 3, neurotrophin 4, placenta growth factor 2, platelet-derived endothelial growth factor, platelet-derived growth factor A chain, platelet-derived growth factor AA, platelet-derived growth factor AB, platelet-derived growth factor B chain, platelet-derived growth factor BB, heparin-binding epidermal growth factor, hepatocyte growth factor receptor, insulin-like growth factor receptor, neurotrophin 3, neurotrophin 4, placenta growth factor 2, platelet-derived endothelial growth factor, platelet-derived growth factor A chain, platelet-derived growth factor AA chain, platelet-derived growth factor BB, platelet-derived growth factor B chain, platelet-derived growth factor B, platelet-binding factor B, heparin-binding protein, and a-binding protein, Platelet-derived growth factor receptor alpha, platelet-derived growth factor receptor beta, pre-B cell growth stimulating factor, stem cell factor receptor, TNF, including TNF0, TNF1, TNF2, transforming growth factor alpha, transforming growth factor beta 1, transforming growth factor beta 1.2, transforming growth factor beta 2, transforming growth factor beta 3, transforming growth factor beta 5, latent transforming growth factor beta 1, transforming growth factor beta binding protein I, transforming growth factor beta binding protein II, transforming growth factor beta binding protein III, tumor necrosis factor receptor type I, tumor necrosis factor receptor type II, urokinase-type plasminogen activator receptor, vascular endothelial growth factor and chimeric proteins and biologically or immunologically active fragments thereof.

In various embodiments, the therapeutic moiety further comprises a chemotherapeutic agent. Chemotherapeutic agents contemplated for use in the agents of the present invention include, but are not limited to, alkylating agents comprising: nitrogen mustards such as methyl-ethylamine, cyclophosphamide, ifosfamide, melphalan (melphalan), and chlorambucil; nitrosoureas such as carmustine (BCNU), lomustine (CCNU) and semustine (methyl-CCNU); ethyleneimine/methyl melamine, such as tetraethylene melamine (TEM), triethylene, thiophosphoramide (thiotepa), hexamethylmelamine (HMM, hexamethyl melamine); alkyl sulfonates, such as busulfan; triazines, such as (dacarbazine (DTIC)); antimetabolites, including folic acid analogs (e.g., methotrexate and trimetrexate), pyrimidine analogs (e.g., 5-fluorouracil, fluorodeoxyuridine, gemcitabine (gemcitabine), cytarabine (AraC, cytarabine), 5-azacytidine, 2 '-difluorodeoxycytidine), purine analogs (e.g., 6-mercaptopurine, 6-thioguanine, azathioprine, 2' -deoxyhomomycin (pentostatin), red hydroxyadenine (EHNA), fludarabine phosphate, and 2-chlorodeoxyadenosine (cladribine, 2-CdA)); natural products, including antimitotic drugs (e.g., paclitaxel); vinca alkaloids, including Vinblastine (VLB), vincristine (vinchristine) and vinorelbine (vinorelbine), taxotere (taxotere), estramustine (estramustine) and estramustine phosphate; epipodophyllotoxins (epipodophyllotoxins), such as etoposide (etoposide) and teniposide (teniposide); antibiotics, such as, for example, adriamycin (actimycin) D, daunomycin (rubidomycin), doxorubicin (doxorubicin), mitoxantrone (mitoxantrone), idarubicin (idarubicin), bleomycin (bleomycin), plicamycin (plicamycin) (mithramycin), mitomycin C, and actinomycin; enzymes such as L-asparaginase; biological response modifiers, such as interferon- α, IL-2, G-CSF and GM-CSF; miscellaneous agents, including platinum coordination complexes such as cisplatin and carboplatin, anthracenediones such as mitoxantrone, substituted ureas such as hydroxyurea, methylhydrazine derivatives including N-Methylhydrazine (MIH) and procarbazine, adrenocortical suppressants such as mitoxan (o, p' -DDD) and aminoacetamide; hormones and antagonists, including adrenocortical steroid antagonists (e.g., prednisone (prednisone) and equivalents, dexamethasone (dexamethasone), and aminoacetamides); progestins such as hydroxyprogesterone caproate, medroxyprogesterone acetate and megestrol acetate; estrogens, such as diethylstilbestrol and ethinyl estradiol equivalents; antiestrogens, such as tamoxifen; androgens, including testosterone propionate and fluoxymesterone/equivalent; antiandrogens such as flutamide, gonadotropin releasing hormone analogues and leuprorelin; and non-steroidal antiandrogens, such as flutamide.

The dose of therapeutic moiety or agent provided is administered at a dose measured, for example, in mg/kg. Contemplated mg/kg doses of the disclosed therapeutic agents include about 1mg/kg to about 60 mg/kg. Specific dosage ranges in mg/kg include about 1mg/kg to about 20mg/kg, about 5mg/kg to about 20mg/kg, about 10mg/kg to about 20mg/kg, about 25mg/kg to about 50mg/kg and about 30mg/kg to about 60 mg/kg. The precise effective amount for a subject will depend upon the weight, size and general health of the subject; the nature and extent of any pathology; and selecting the therapeutic agent or combination of therapeutic agents for administration. A therapeutically effective amount for a given situation can be determined by routine experimentation within the skill and judgment of the clinician.

As used herein, an "effective amount" refers to an amount of an agent of the invention sufficient to visualize an identified disease or condition, or to exhibit a detectable therapeutic or inhibitory effect. The effect is detected, for example, by an improvement in clinical condition or a reduction in symptoms. The precise effective amount for a subject will depend upon the weight, size and general health of the subject; the nature and extent of the pathology; and selecting the therapeutic agent or combination of therapeutic agents for administration. A therapeutically effective amount for a given situation can be determined by routine experimentation within the skill and judgment of the clinician.

Visualization of reagents

Binding to colon cells is visualized by any method known to one of ordinary skill in the art. As discussed herein, visualization is, for example, but not limited to, in vivo, ex vivo, in vitro, or in situ visualization.

In one embodiment, visualization is by imaging and can be performed with a wide area endoscope (olympus, tokyo, japan) specifically designed to collect fluorescence images with high spatial resolution on a macroscopic scale (millimeters to centimeters) over large mucosal surface areas. This ability is needed to quickly screen large surface areas, such as those found at the distal end of the esophagus during Endoscopy, to locate areas of suspicious disease [ Wang et al, gastroenterological Endoscopy 1999; 49:447-55]. This technique has been adapted for fluorescence detection and is compatible with dye-labeled probes. The instrument can be imaged in three different modes, including White Light (WL), Narrow Band Imaging (NBI), and fluorescence imaging. Narrow band imaging is a new technology that represents a variation of conventional white light illumination by limiting or narrowing the wavelength range by changing the spectrum with filters.

This method enhances contrast in the endoscopic image by adjusting the light to maximize absorption of hemoglobin present in the vasculature of the metaplastic region of the intestine, thereby providing more visual detail of the esophageal mucosa. WL and NBI images were collected by the central objective and fluorescence images were collected by the second objective located at the periphery. There is a distance of about 3mm between the centers of the white light and the fluorescent objective lens, which results in only a slight registration error of the two images. In addition, an air/water nozzle was used to remove debris from the objective lens, and a 2.8mm diameter instrument channel was used to deliver the bioptome. The objective lens is forward looking, having a 140 degree field of view (FOV) defined by the maximum illumination angle. The depth of field (DOF) of the WL/NBI imaging mode is defined by the range of distances between the distal end of the endoscope to the mucosal surface, thereby focusing the image, which is 7 to 100mm, and for fluorescence, which is 5 to 100 mm. The lateral resolution of WL/NBI measured at 10mm from the mucosa was 15 μm, which for fluorescence was 20 μm. The xenon light source provides illumination for all three modes, as determined by a filter wheel located in the image processor. Illumination for all three imaging modes is provided by two fiber optic light guides. In the WL mode, the full visible spectrum (400 to 700nm) is provided, while in the NBI mode, the filter wheel narrows the spectral bands of the red, green and blue regions. In fluorescence mode, the second filter wheel enters the illumination path and provides fluorescence excitation in the 395 to 475nm spectral band. Further, illumination at 525 to 575nm provides reflected light in the green spectral range centered at 550 nm. The fluorescence image was collected by a CCD detector located at the periphery with a 490-625 nm band-pass filter to block the excitation light. The normal mucosa emits bright autofluorescence, and thus the composite color is bright green. The intensity is shown to decrease due to increased vasculature uptake of autofluorescence in the neoplastic mucosa.

The medical endoscope can be used to capture images of the colon after reagent administration and incubation using 1) white light, 2) narrow band and fluorescence. After entering the colon, 5 seconds of video was collected and digitized in white light and narrow band imaging mode. Imaging in this mode was used to assess the spatial extent of intestinal metaplasia to comprehensively assess polypeptide binding. Approximately 3ml of fluorescently labeled peptide was then topically applied to the colon at a concentration of 10 μ M using a spray catheter, carefully covering the entire mucosa. The amount of the agent of the present invention may be determined by one of ordinary skill in the art.

In some embodiments where the detectable label is a radiolabel, the radiolabel is detected by nuclear imaging. Nuclear imaging is understood in the art as a method of generating an image by detecting radiation from different parts of the body after administration of a radiotracer material. Images were recorded on a computer and film.

Other methods according to the present disclosure involve obtaining a tissue sample from a patient. The tissue sample is selected from the group consisting of a tissue or organ of the patient.

Formulations

In various aspects, the compositions of the present invention are formulated with pharmaceutically acceptable excipients, such as carriers, solvents, stabilizers, adjuvants, diluents, and the like, depending on the particular mode of administration and dosage form. The compositions are generally formulated to achieve a physiologically compatible pH, and range from about pH 3 to about pH 11, or from about pH 3 to about pH7, depending on the formulation and route of administration. In alternative embodiments, the pH is adjusted to a range of about pH 5.0 to about pH 8. In various aspects, the compositions include a therapeutically effective amount of at least one compound as described herein, and one or more pharmaceutically acceptable excipients. Optionally, the compositions comprise a combination of compounds described herein, or may include a second active ingredient for treating or preventing bacterial growth (such as, but not limited to, an antibacterial or antimicrobial agent), or may include a combination of agents according to the present disclosure.

Suitable excipients include, for example, carrier molecules comprising large, slowly metabolized macromolecules such as proteins, polysaccharides, polylactic acids, polyglycolic acids, polymeric amino acids, amino acid copolymers, and inactivated virus particles. Other exemplary excipients include antioxidants (such as, but not limited to, ascorbic acid), chelating agents (such as, but not limited to, EDTA), carbohydrates (such as, but not limited to, dextrins, hydroxyalkyl celluloses, and hydroxyalkyl methylcelluloses), stearic acid, liquids (such as, but not limited to, oils, water, physiological saline, glycerol, and ethanol), humectants or emulsifiers, pH buffering substances, and the like.

The following examples are presented by way of illustration and are not intended to limit the scope of the subject matter disclosed herein.

Examples

Example 1

Cell lines, media and chemicals

Human CRC cell lines HT29, SW480, CCD841 and mouse embryonic fibroblast cell line NIH3T3 were obtained from the american type culture collection (ATCC, Manassas, VA). The S114 cell line contained NIH3T3 cells transformed with human HGF/SF and Met and expressed cMet. We used McCoy 5A medium (Gibco) to culture HT29 cells and Dulbecco' S modified Eagle medium (Gibco) to culture SW480, NIH3T3 and S114 cells. Eagle minimal essential medium (Lonza) was used for CCD841 cells. All cells were incubated at 37 ℃ with 5% CO₂Cultured in medium and supplemented with 10% Fetal Bovine Serum (FBS). Cells were passaged using 0.25% trypsin with EDTA (Mediatech, Manassas, VA). The cell number was quantified on a hemocytometer. Peptide synthesis reagents were obtained from Anaspec (Fremont, CA) or AAPPTEC (AAPPTEC, Louisville, KY), the highest grades available (C:)>99% pure) was used without further purification. Solvents and other chemicals were purchased from Sigma-Aldrich (st. louis, MO) unless otherwise noted.

cMet specific peptides

Heptapeptide phage display libraries (Ph.D. -7New England Biolabs) were used for biopanning against the extracellular domain of purified cMet protein, i.e., cMet-ECD (10692-H08H, Sino Biological Inc.)³². The candidate phage with the highest enrichment was selected for further evaluation. The reactivity of HT29 cells was assessed using enzyme-linked immunosorbent assay (ELISA). Binding interaction between candidate peptide and cMetEffect non-complete structures 1UX3 and 2UZX Using Pepsite software⁵⁵Evaluation was performed. Using the protocol described above, phages containing the QQTNWSL (SEQ ID NO:1) (QQT) peptide were enriched after 4 rounds of biopanning. A random, scrambled, reordered sequence, TLQWNQS (SEQ ID NO:3) (TLQ), was used as a control. Peptides were synthesized using standard Fmoc-mediated solid phase chemistry³³The C-terminus of the peptide was labeled with the NIR dye Cy5.5(Lumiprobe, Hallandale Beach, FL) via a 5-amino acid (GGGSK; SEQ ID NO:2) linker. The synthesis of both peptides was performed with a PS3 automated synthesizer (Protein Technologies inc., Tucson, AZ). Fmoc and Boc protected L-amino acids were used and assembled on rink amide MBHA resin. The C-terminal lysine was incorporated as Fmoc-lys (ivDde) -OH and the N-terminal amino acid was incorporated with Boc protection to avoid removal of excess Fmoc during ivDde partial deprotection prior to fluorophore labelling. After completion of the synthesis, the ivDde side chain protecting groups were removed with 5% hydrazine in DMF (3 × 10 min) under continuous stirring at Room Temperature (RT), and the resin was then transferred to a reaction vessel for manual dye labeling. The resin was washed with DMF and DCM for 3X 1 min. The protected resin-bound peptide was incubated with Cy5.5-NHS ester overnight in the presence of DIEA and incubated at room temperature with stirring for 24-48 hours and the completion of the reaction was monitored by qualitative ninhydrin test. The peptide was then cleaved from the resin with cooled trifluoroacetic acid (TFA), triisopropylsilane, water (9.5:0.25:0.25, v/v) in the dark with stirring at room temperature for 4 hours. Separating the peptide from the resin, and applying N to the filtrate₂The gas was evaporated and then precipitated with cold ether during overnight incubation at-20 ℃. The precipitate was centrifuged at 3000rpm for 5 minutes and washed 3 times with ether. Suspending the crude peptide in 1:1 acetonitrile: H₂O (v/v) and purified by high performance liquid chromatography with C18 column (Waters, Milford, MA) using a water (0.1% TFA) -acetonitrile (0.1% TFA) gradient. The final purity of the peptide was confirmed using an analytical C18 column. Mass spectrometry (MALDI-TOF, Bruker AutoFlex Speed) was used to measure the mass-to-charge ratio (m/z) of the product.

Spectral measurement

The absorption spectra of the peptides were measured using a uv-vis spectrophotometer (NanoDrop 2000, Thermo Scientific) and the fluorescence emission was collected using a fiber coupled spectrophotometer (Ocean Optics) with a diode pumped solid state Laser (technical Laser Inc.) excited at λ ex ═ 671 nm. The spectra were plotted using Origin 6.1 software (Origin lab Corp).

Confocal fluorescence microscope

HT29, SW480, S114 and NIH3T3 cells were seeded in 12-well cell culture plates with circular glass coverslips to about 80% confluence. Cells were blocked with 1 × PBS plus 2% BSA for 1 hour at 4 ℃, then incubated with 5 μ M peptide for 10 minutes at room temperature in the dark, washed three times, fixed with 4% PFA for 5 minutes, washed with 1 × PBS, and then mounted on glass slides with dalip-containing ProLong Gold reagent (Invitrogen, Waltham, MA). As a positive control, after blocking with 2% BSA at 4 ℃ for 1 hour, 1:3000 diluted rabbit anti-cMet monoclonal primary antibody (Cell Signaling Technology, #8198) was incubated with the cells at 4 ℃ overnight. Thereafter, the cells were washed three times with 1 × PBS and further incubated with a 1:500 dilution of AF 488-labeled goat anti-rabbit immunoglobulin G secondary antibody (Life Technologies, # a-11029) for 1 hour at room temperature, washed three times, and then mounted on a slide using daling Gold reagent containing DAPI. Confocal fluorescence images were collected using a 63X oil immersion objective (Leica SP5 inserted 2-Photon FLIM focal). Fluorescence intensity from five cells in two independent images was quantified using custom-made matlab (mathworks) software.

Down-Regulation of cMet with siRNA

We reduced cMet protein levels with siRNA and then assessed the binding of QQT-cy5.5 and TLQ-cy5.5 to the surface of si-cMet transfected HT29 cells to verify specific peptide binding. We used siRNA1(SASI _ Hs01_00133002, Sigma) for HT29, siRNA2(SASI _ WI _00000001, Sigma) for S114, and

siRNA #1 universal negative control (SIC001, Sigma) was used for negative control. We transfected the cells with Lipofectamine 2000(11668027, Invitrogen) according to the manufacturer's instructions. Knock-down of cMet was confirmed by western blotting (fig. 18). Cells were incubated with 5 μ M peptide at RT (i.e., room temperature) for 5 minutes, then with DAPI-containing peptides as described previouslyProLong Gold reagent was fixed and mounted on a glass slide. As a positive control, a 1:3000 dilution of monoclonal rabbit anti-cMet primary antibody (Cell Signaling Technology, #8198) was incubated with the cells, fixed with ProLong Gold reagent containing DAPI and mounted on a slide. Confocal fluorescence images were collected using a 63X oil immersion objective (Leica SP5 inserted 2-Photon FLIM focal).

Competition for peptide binding

We used the labeled QQT-Cy5.5 with unlabeled QQT or recombinant human hepatocyte growth factor (HGF,194-HG-005, R)&D) Competition analysis between to verify the specific binding of qqtx-cy5.5 to HT29 cells. In triplicate, make approximately 10³Individual HT29 cells were grown to approximately 70% confluence on coverslips. Unlabeled QQT and 0, 25, 50, 100, 200 and 400 μ M TLQ peptide or 0, 5, 10, 25, 50 or 100ng/mL HGF were added first and incubated with the cells at 4 ℃ for 30min (i.e. minutes). Cells were washed three times with 1X PBS and then incubated with 5 μ M QQT-cy 5.5 for a further 30min at 4 ℃. Cells were washed three times with 1X PBS and then fixed with 4% PFA for 10 min. Cells were washed with 1 × PBS and fixed with ProLong Gold reagent containing dapi (invitrogen). Confocal fluorescence images were collected at each concentration using a 63X objective (Leica SP5 inserted 2-Photon FLIM focal) and the intensities of five cells in three independent images were quantified using custom Matlab (Mathworks, nature, MA) software.

Effect of peptides on cell signalling

HT29 cells were starved overnight with serum-free medium prior to incubation with hgf (hgf, 294-HG-005, R & D) or peptide. Recombinant human HGF protein was added to HT29 cells at a concentration of 25ng/ml for 10, 30 or 120 minutes in different wells. QQT-cy 5.5 and TLQ-cy 5.5 were added at concentrations of 5 or 100 μ M for 10, 30 and 120 minutes. Peptides were added at concentrations of 5 and 100 μ M for 10, 30 or 120 minutes. Cells were then washed with 1X PBS and lysed with Pierce RIPA buffer containing a mixture of Halt phosphatase inhibitors (Thermo Fisher) and a mixture of Halt protease inhibitors (Thermo Fisher). Protein content was quantified by bicinchoninic acid assay (BCA). anti-cMet antibody (Cell Signaling, #8198), phospho-cMet (Tyr1234/1235) antibody (Cell Signaling, #3077), anti-AKT antibody (Cell Signaling, #4691), anti-phospho-AKT antibody (Cell Signaling, #9271), anti-ERK 1/2 antibody (Abcam,

# ab17942), anti-phospho-ERK 1/2 antibody (Abcam, # ab50011) and anti-tubulin antibody (Invitrogen, #32-2600) were used according to the manufacturer's instructions.

Alamar blue assay was performed using HT29 and CCD841 cells. After overnight culture in serum-free medium, about 3X 10³Individual cells were seeded in serum-free medium in each well of a 96-well plate at a final volume of 100 μ Ι _ per well. Cells were incubated with HGF (25ng/mL) or peptide (5 and 10. mu.M) for 48 hours at 37 ℃. An amount of alamarblue reagent (10. mu.L) corresponding to 10% of the pore volume was added and incubated at 37 ℃ for 4 hours. The fluorescence excited at λ ex-530-.

Characterization of peptide binding

We assessed the binding affinity of QQT x-cy5.5 to HT29 cells by measuring the apparent dissociation constant. HT29 cells were blocked with 0.5% BSA, and then approximately 10 cells were blocked⁵The cells and concentration of 0, 10, 25, 50, 75, 100, 125, 150 or 200nmol/L QQT Cy5.5 at 4 degrees C temperature 1h incubation. The cells were then washed 3 times with 1 XPBS containing 0.5% BSA to remove unbound peptides and then analyzed by flow cytometry (FACS Canto; BD Biosciences, San Jose, Calif.). Nonlinear regression analysis was performed using Origin 6.1 data analysis software (Origin lab, Northampton, MA) and the equilibrium dissociation constant K was calculated using the sample mean_D。K_D＝1/K_ABy applying a nonlinear equation I [ X ]]＝(I₀+I_maxk_a[X])/(I₀+k_a[X]) And performing least square fitting calculation on the data to obtain the target. I is₀And I_maxInitial and maximum fluorescence intensities corresponding to no peptide and peptide saturation, respectively, and [ X [)]Indicates the concentration of the binding peptide³⁴。

The time scale of the binding of QQT x-cy 5.5 to HT29 cells was assessed by measuring the apparent binding time constant k. HT29 cells were blocked with 0.5% BSA, and then approximately 10 cells were blocked⁵The cells were incubated with 5. mu.M QQT-Cy5.5 at 4 ℃ for a time interval of 0 to 20 minutes. Cells were then washed 3 times with cold 1X PBS containing 0.5% BSA to remove unbound peptides. After centrifugation, cells were fixed with 4% PFA at 4 ℃ for 30 minutes and then analyzed by flow cytometry. The median fluorescence intensity (y) at different time points (t) was taken as the ratio to HT29 cells without peptide addition using Flowjo software (LLC, Ashland, OR). The rate constant k is determined by fitting the data to a first order kinetic model y (t) ═ I_max[1-exp(-kt)]Calculation of wherein I_maxIs maximum, Prism 5.0 software (GraphPad, La Jolla, Calif.) was used.

The interaction between the peptide and mouse cMet was assessed using the pull-down assay (Paul et al, Methods 54:387-395 (2011)). Peptides were immobilized on EHS active beads (17-0906-01, GE) and incubated with purified mouse cMet-ECD protein (50622-M08H, Sino Biological). After washing, bound proteins were detected by western blot (fig. 18).

Organoid specimens

Patient specimen information is listed in table 1. The normal specimen (#87) in this study was from tissue of a deceased donor; while adenomatoid organs are from large adenomas of biopsies: #245 (sessile sawtooth); #590 (tubular); #584 (tubular 20 mm); and #236 (FAP).

To validate the samples, Short Tandem Repeat (STR) analysis was used to identify 15 tetranucleotide repeat sites in human genomic DNA (AMPFLSTR Identifier Plus Assay, Applied Biosystems; University of Michigan DNA Sequencing Core), and furthermore, an amelogenin sex determination marker was run on a 3730XL Gene Analyzer (Applied Biosystems). Cultures are often tested for mycoplasma contamination using the Lonza MycoAlert kit (service of UMICH Transgenic Animal Model Core).

TABLE 1

TABLE 1 patient-derived colon Normal and adenomatous organoids. Targeted colorectal cancer DNA sequencing plates were used to determine if there were variations in 71 different oncogenes and tumor suppressor genes, which are commonly mutated in colorectal cancer. A stop codon (); and (7) code shifting (FS).

Organoid culture

Human organoid cultures have previously been established from normal and adenomatous tissues^36-38And supplied by the translation Tissue Modeling Laboratory (TTML; University of Michigan).

Cultures were grown in matrigel (diluted to 8mg/mL with growth medium; Corning, #354234) in 6-well tissue culture plates (USA Scientific CytoOne, # CC 7682-7506). The cultures were passaged by grinding and separating matrigel in cold Dulbecco's Phosphate Buffered Saline (DPBS), centrifuging at 300Xg, and plating on the first day with 2.5. mu.M CHIR99021 (Tocris; 4423), a highly selective GSK3 inhibitor, and 10. mu. M Y27632 (Tocris; TB1254-GMP/10), a highly selective p160ROCK inhibitor.

Normal (#87) and sessile serrata (#245) organoids were cultured in LWRN complete medium containing 50% L-WRN conditioned medium (sources of Wnt3a, R-spondin-3, and Noggin)³⁹Higher DMEM/F-12(Gibco, 12634028), N-2 medium supplement (Gibco; #17502048), B-27 supplement minus vitamin A (Gibco; #12587010), 1mM N-acetyl-L-cysteine (Sigma-Aldrich, A9165), 2mM GlutaMax (Gibco, #35050-&D Systems,Inc.,236-EG)、10μM SB202190(Sigma-Aldrich；S7067)、500nM A83-01(R&D Tocris, #2939) and 10 μ M Y27632 (Tocris; TB 1254-GMP/10). FAP adenomas (#236) were cultured in LWRN complete medium without SB 202190.

Tubular adenomatoid (#590) is cultured in Stemline complete Medium, which contains Stemline^TMKeratinocyte medium II (Sigma S0196) supplemented with Stemline growth supplement (Sigma S9945), 2mM GlutaMax, 4mM L-glutamine and 50. mu.g/ml Primocin. Prior to harvesting for transplantation, #590 culture was treated with 5 μ M Y27632 for 18 hours. Tubular adenomatous organoid #584 was completely cultured in 50% of the above Stemline complete medium and 50% of the above LWRNCulturing in the medium.

Cultures were harvested from matrigel in cold DPBS, ground 30-fold with a 1mL pipette tip, and centrifuged at 300xg for 3 minutes at 4 ℃. Organoid particles were resuspended in 10mL cold DPBS and mechanically dissociated using a mild MACS Octo dissociator (Miltenyi Biotec; 130-. Organoid fragments were further dissociated by 20X pipetting using a 1mL pipette tip. Large debris was removed with a 100 μm BSA coated cell filter (Corning, DL 352360). Centrifugation was performed slowly at 100Xg to reduce single cell content. Cell aggregates were resuspended in cold DPBS supplemented with 5% matrigel and 10 μ M Y27632. All plastic articles, including the mild MACS C tubes (Miltenyi; 130-.

Organoid transplantation

Acute colitis was induced in 8-week-old NOD.Cg-Prkdcscid Il2rgtm1Wjl/SzJ mice (005557, Jackson laboratory) by feeding them with 3.0% DSS (molecular weight 40,000; Cat # AAJ 6360622; Alfa Aesar) dissolved in water for 5 days (d)^40,41. On day 6, donor organoids were released from collagen type I gels, dissociated with EDTA, and washed with PBS containing BSA as a passaging procedure. Approximately 2.5-5E5 cell aggregates in 200. mu.L were transplanted into each mouse as described previously^42,43. The organoids were instilled as a suspension into the lumen of the colon using a syringe and a thin flexible catheter 4 cm in length and 2mm in diameter. The anal margin was glued for 6 hours after infusion to prevent immediate drainage of the lumen contents, and then the glue was removed with ethanol. Mice were reared as usual after transplantation. Mice were housed in pathogen-free conditions and were supplied ad libitum with water under controlled humidity (50 ± 10%), light (12/12 hours light/dark cycle) and temperature (25 ℃). Anesthesia is induced and maintained by a nasal cone, and isoflurane is inhaled to mix with oxygen at a concentration of 2-4% and at a flow rate of about 0.5L/min. Organoid imaging was performed 3 weeks after transplantation.

CPC; apc mouse model

CPC that can develop spontaneous adenomas in the distal colonic epithelium has also been used; apc mouse model⁴⁴. Under the control of the Cdx2 promoter (Cdx2P-9.5NLS-Cre), Cre recombinase can occasionally delete Adenomatous Polyposis Coli (APC) alleles, resulting in polyploid colon adenomas or applanation lesions. We collected images of mice varying in age from 7 to 10 months (n-8).

Peptide in vivo imaging

In vivo imaging was performed with approval from the institutional animal use and care committee at michigan university. CPC; apc mice are used for in vivo imaging. The mouse strain is genetically engineered to occasionally delete an Adenomatous Polyposis (APC) allele under the control of the Cdx2 promoter (CDX2P-9.5NLS-Cre), resulting in the spontaneous formation of flattened or polyploid adenomas in the distal colon (Hinoi et al, Cancer Res 67:9721-9730 (2007)). Mice were housed in pathogen-free conditions and were supplied ad libitum with water under controlled humidity (50 ± 10%), light (12/12 hours light/dark cycle) and temperature (25 ℃). Mice were fasted for 4-6 hours prior to imaging. Anesthesia is induced and maintained by nose cone, and isoflurane is inhaled and mixed with oxygen at concentration of 2-4% and flow rate of 0.5L/min.

A rigid small animal endoscope (Karl Sorz Veterinary endoscope) was inserted into the rectum (Liu et al, Gut 62:395-⁴⁵. Mucus and debris in the distal colon were removed by vigorous flushing with warm tap water 3 times. White light illumination was first applied to identify the presence of adenomas. The distance between the endoscope tip and the anus and the clockwise position of the polyp are recorded. The QQT x-cy 5.5 solution (100 μ M, 1.5mL) was delivered locally to the distal colon through the instrument channel (3 Fr). After 5 minutes of incubation, unbound peptides, feces and debris were rinsed 3 times with warm tap water before image collection. After 3 days, the clearance of the QQT-cy5.5 signal was confirmed endoscopically, and then the same mice were imaged using TLQ-cy5.5 as a control. The ratio of the fluorescence and reflectance images is determined to correct for differences in distance and geometry over the field of view (FOV) of the images (Joshi et al, Endoscopy 48: A1-A13 (2016)). A total of 3 sizes of 20X 20 μm were randomly identified from the location of the adenoma (target) and the adjacent normal colonic mucosa (background)²The independent area of (a).

The mean fluorescence intensity was used to calculate the target to background (T/B) ratio. The images were processed and analyzed using custom software in Matlab (Mathworks) (Joshi et al, Gastroenterology 152:1002-1013e1009 (2017)). Fluorescence intensity was quantified using Matlab software. Correcting the fluorescence intensity of the region of interest (ROI) by the ratio of fluorescence to reflectance, targeting the fluorescence of the region of interest (T), selecting the normal colon region of the adjacent mouse with the same area as the background (B)⁴⁶. The flow showing the least motion artifacts and no debris (stool, mucus) was selected for image quantification. A single frame is derived using custom Matlab software. Ex vivo validation of high expression of cMet in mouse Colon neoplasia

After imaging was complete, mice were euthanized. The colon is excised and divided longitudinally, the colon is excised, rinsed with PBS, and opened longitudinally for imaging with NIR fluorescence (NIR fluorescence imaging System) ((R))

LI-COR Biosciences). Images were collected at 85 μm resolution using λ ex-685 nm and λ em-720 nm. The images were analyzed using custom software (Image Studio, Li-Cor Biosciences). The background was measured using normal colon regions of equal area adjacent to polyps. Prism software (v6.02, GraphPad) was used to plot the data.

CPC with IHC; increased expression of cMet in colorectal adenomas in Apc mice and human proximal colon neoplasias

Serial formalin-fixed sections 10 μm thick were prepared, deparaffinized, and antigen retrieval was accomplished using standard methods. Briefly, sections were incubated in xylene for 3 minutes 3 times, washed with 100% ethanol for 2 minutes 2 times, and washed with 95% ethanol for 2 minutes 2 times. Slicing at dH₂Incubate for 5 minutes 2 times in O for rehydration. The antigen was exposed to boiling 10mM 1X pH6.0 citrate buffer for 10 minutes. After cooling at Room Temperature (RT) for 20-30 min, sections were mounted in dH₂Wash in O for 2min 3 times. Sections were cut at 3% H₂O₂Incubated for 10 minutes to block endogenous peroxidase activity. Slicing at dH₂Wash in O for 5 minutes three times and in phosphate buffered saline containing tween 20(PBST) for 5 minutes.Blocking was performed with 10% normal goat serum or DAKO protein blocking agent (X0909, DAKO) for 45 min at room temperature. Sections were incubated overnight at 4 ℃ with 1:100 dilutions of monoclonal rabbit anti-cMet antibody (Abcam, EP1454Y, ab51067) containing 2.5% normal goat serum and washed 5 min 3 times in 0.1% TBST. Goat anti-rabbit secondary antibody (Abcam, ab150077) diluted 1:200 was applied to each section and incubated for 30 minutes at room temperature. A control was prepared using the same method, but without the addition of anti-cMet primary antibody. Secondary antibodies were removed by washing in 0.1% TBST for 5 minutes 3 times. The sections were then incubated in a pre-mixed Elite Vectastain ABC reagent (Vector Labs, PK-6100) for 30 minutes at room temperature. Sections were washed 5 min 3 times in 0.1% TBST and developed with 3,3' -diaminobenzidine substrate. The reaction was monitored for 1-3 minutes, and then immediately after the section developed by immersing the slide in dH₂The reaction was quenched in O. Hematoxylin was added as a counterstain for about 20 seconds, and then the sections were dehydrated in increasing concentrations of ethanol (70%, 80%, 95%, 100%). Using Permount^TMMounting media (Fisher, Pittsburgh, Pa., # SP15-100) fixed the coverslips in xylene. Histology of serial sections (H)&E) And (6) processing. A control was prepared using the same method, but without the anti-cMet primary antibody. Processing serial sections for routine histology (H)&E)。

In CPC; immunofluorescence staining of cMet with QQT-Cy5.5/antibody in Apc mouse colonic adenomas and human proximal colon neoplasia

Mouse colonic adenoma specimens were harvested, formalin-fixed, and paraffin-embedded. Specimens of tubular adenomas of the human proximal colon (n ═ 21), sessile serrated adenomas (n ═ 13), hyperplastic polyps (n ═ 7), and normal colonic mucosa (n ═ 10) were taken from the tissue bank at the department of pathology, michigan university. Human specimens were treated identically to mouse colon specimens. Sections (5 mm thick) were cut and mounted on glass slides (Superfrost Plus; Fischer Scientific). Serial 5 μm sections were deparaffinized and antigen retrieval was performed as described above. Sections were blocked with 10% goat normal serum (Fisher Scientific,50062Z) for 10 min at room temperature and then washed with PBS. Sections were incubated with 5 μ M QQT-cy 5.5 and 2% BSA for 10 min at room temperature. Then slicing the slices with0.1% PBST was washed 3 times and further incubated with 1:200 diluted anti-cMet primary antibody (Cell Signaling Technology, #8198) and 2% BSA at room temperature for 2 hours in the absence of light. Sections were washed 3 times with 0.1% PBST for 3 minutes each, then incubated with 1:500AF 488-labeled goat anti-rabbit secondary antibody (Abcam, ab150077) and 2% BSA for 1 hour at room temperature in the dark. After 3 washes with 0.1% PBST for 3 minutes each, sections were mounted with Prolong Gold reagent containing dapi (invitrogen). Histology of adjacent sections (H)&E) And (6) processing. We will size 3 20X 20 μm²The cassette of (a) was placed completely within the colon epithelium in each image and the mean fluorescence intensity was measured using custom-made Matlab software. Regions of saturated intensity are avoided.

Example 2

cMet specific peptides

The linear heptapeptide sequence QQTNWSL (SEQ ID NO:1) was identified by biopanning a highly diverse phage display library of linearized heptapeptides against the extracellular domain (ECD) of cMet. Using a structural model of cMet, the peptide showed the lowest P value for the binding interaction. The C-terminus of the peptide (black) was covalently linked to the fluorophore cy5.5 (red) via a GGGSK linker (blue), hereafter referred to as QQT-cy5.5, fig. 1A. The linker separates the peptide from the fluorophore to prevent steric hindrance. The scrambled sequence TLQWNQS (SEQ ID NO:3) was also labelled with Cy5.5 for use as a control, hereafter referred to as TLQ-Cy5.5, FIG. 1B. The three-dimensional model shows the differences in biochemical structure, FIG. 1C, D. Peak absorption and emission of the cy5.5 labeled peptides occurred in the Near Infrared (NIR) spectrum, fig. 1E, F, where hemoglobin absorption, tissue scattering and tissue autofluorescence were minimal. Tissue penetration depth is greatest and hemoglobin absorption, tissue scattering and tissue autofluorescence have minimal impact in this protocol. The peptide synthesized by HPLC was greater than 95% pure and the experimental mass to charge ratio (m/z) measured using mass spectrometry was 1827.67, consistent with the expected values, fig. 9.

Example 3

Validation of binding to cells in vitro

siRNA knock-down experiments were performed using HT29 human colorectal cancer cells to verify specific binding of QQT-cy 5.5 to cMet. Under confocal microscopy, QQT-cy5.5 (red) and AF488 labeled anti-cMet antibody (green) strongly bound to the surface of control HT29 cells transfected with siC (control) (arrow), fig. 2A, B, while TLQ-cy5.5 showed minimal binding, fig. 2C. A decrease in fluorescence intensity was observed using HT29 knockdown cells (sicMet), fig. 2D, E, and TLQ-cy 5.5 with little signal, fig. 2F. The quantification results show that this drop is significant, fig. 2G. Western blot shows the effect of cMet expression knock down in cells, fig. 2H. Furthermore, significantly higher fluorescence intensity was observed for qt — -cy5.5 and anti-cMet-AF 488 in combination with HT29 cells (cMet +) compared to SW480 human colorectal cancer (cMet-) cells, fig. 10. Similar results were found using mouse S114(cMet +) and NIH3T3(cMet-) cells, fig. 11.

Example 4

Peptide characterization

Specific binding of QQT-cy 5.5 to cMet was confirmed by adding unlabeled QQT to compete for binding. A significant decrease in fluorescence intensity was observed in a concentration-dependent manner, fig. 3A. These results indicate that the peptide, rather than the linker or fluorophore, mediates the binding interaction. In contrast, the fluorescence intensity of QQT x-cy 5.5 binding to HT29 cells did not change with the addition of Hepatocyte Growth Factor (HGF), a known ligand for cMet, at concentrations ranging from 0 to 100ng/mL, fig. 17A. By comparison with TLQ, the pull-down analysis showed a strong band from QQT binding to mouse cMet-ECD, fig. 17B. Co-localization of qtt-cy 5.5 (red) and anti-cMet-AF 488 (green) binding to the HT29 cell surface (arrows) was observed on the merged images with a Pearson correlation coefficient ρ ═ 0.73, fig. 3B. Measurement of k binding of QQT x-cy 5.5 to HT29 cells using flow cytometry_dApparent dissociation constant 57nM, fig. 3C, and k 0.62min was measured for the same cells^-1(1.6min), which supports rapid binding for topical application, fig. 3D.

Example 5

Effect of peptides on cell signalling

Hepatocyte Growth Factor (HGF) is a known ligand for cMet and was incubated with HT29 cells (cMet +) as a positive control. Strong phosphorylation activity of cMet (p-cMet), downstream AKT (p-AKT) and ERK1/2(p-ERK1/2) was observed on Western blots, FIG. 4. However, the addition of QQT at concentrations of 5 or 100 μ M did not result in a change in phosphorylation of any of these downstream cellular signaling markers.

More specifically, no competition was observed between QQT and HGF, which supports the lack of interaction and effect on downstream signaling, fig. 17A. These results indicate that peptide and HGF bind to different sites on the cMet target. Western blots were performed to assess markers of downstream cell signaling activation, fig. 4A. Incubation of HGF (positive control) with HT29 cells showed strong phosphorylation activity of cMet (p-cMet), downstream AKT (p-AKT) and ERK1/2(p-ERK 1/2). In contrast, the addition of QQT x-cy 5.5 at concentrations of 5 and 100 μ M did not result in any change in the phosphorylation of the substrate. The alamarbape blue assay showed no effect on the growth of HT29 and CCD841 cells compared to HGF at 5 or 100 μ M qt x-cy5.548 h addition, fig. 4B, C. CCD841 Normal Colon cells were used to assess the effect of peptides on cell phenotype in non-tumor cells.

Example 6

In vivo imaging of genetically engineered CRC mice

The results of the pull-down assay support the specific binding of QQT x-cy 5.5 to mouse cMet-ECD, fig. 17B. Rigid small animal endoscopes are used to collect CPCs; in vivo images of Apc mice. Displaying the CPC using a white light image collected by the small animal endoscope; no polyps were visibly evident in the colon of Apc mice (arrows), fig. 12A. The mouse is genetically engineered to delete an Apc allele in the Cre regulated lower body cell and spontaneously form flat adenomas and polyploid adenomas. QQT-cy 5.5 was then applied topically, incubated for about 5 minutes, and unbound peptides were washed away. NIR fluorescence images collected after staining with QQT x-cy 5.5 showed the presence of flat lesions (arrows), fig. 12B. Fluorescence registered reflectance images were obtained, fig. 12C. Fluorescence images collected 3 days later from the same lesion using TLQ x-cy 5.5 (control) showed almost no signal, fig. 12D. Similar results were obtained from representative polyploid lesions, fig. 5E-H. The ratio of fluorescence and reflectance images from flat lesions was determined to correct for differences in distance and geometry over the image field of view (FOV) to allow accurate quantification of image intensity, fig. 5I. The fluorescence, reflectance and ratio values for the dashed lines in fig. 5I are shown, fig. 5J. Images collected from polyps are similarly processed. White light images collected in different mice showed the presence of polyps (arrows), fig. 12E (see also fig. 14A). The fluorescence images collected show strong intensity from premalignant lesions (arrows), fig. 12F. Fluorescence registered reflectance images were obtained, fig. 12G. Fluorescence images collected 3 days later with TLQ x-cy 5.5 from the same polyp showed minimal signal, fig. 12H. The ratio of fluorescence and reflectance images from the flat lesion in fig. 12A is used to correct for differences in distance and geometry across the image field of view and allows accurate quantification of image intensity, fig. 12I. The fluorescence, reflectance and ratio values for the dashed lines in FIG. 12I are shown, FIG. 12J. The mean T: B ratio of QQT-cy 5.5 was found to be significantly greater than the T: B ratio of TLQ-cy 5.5 for polyps and flat lesions, fig. 12K and 14G. Histology (H & E) of flat lesions and polyps showed adjacency to normal colonic mucosa and feature low grade dysplasia, fig. 12L, M.

Example 7

Macroscopic validation of isolated mouse Colon

After imaging is completed, the CPC is performed; apc mice were euthanized, coloboma excised and separated longitudinally, exposing mucosal surfaces for collection of macroscopic white light and fluorescence images, fig. 5L, M and 13A, B. Polyp locations were co-localized on the white light and fluorescence images, fig. 13C. In n-5 mice, mean fluorescence intensity from dysplasia was found to be significantly higher compared to adjacent normal colonic mucosa in the n-10 region, fig. 13D. Immunohistochemistry with known antibodies was performed to verify increased expression of cMet in mouse dysplasia, fig. 13E, which is compared to normal colonic mucosa, fig. 13F.

This ex vivo imaging verified the specific binding of QQT x-cy 5.5 to cMet. The colon is excised and divided longitudinally to expose the mucosal surface. The co-localization of polyps can be seen on the merged image, fig. 5N. The boundaries of adenomas are clearly visible. The mean fluorescence intensity of polyps was significantly higher than that of the adjacent normal colonic mucosa, fig. 5O. Using Immunohistochemistry (IHC), cMet was increased in mouse adenomas compared to normal colon, fig. 5P, Q.

Example 8

Microscopic verification of mouse colon in vitro

Confocal microscopy was used at CPC; increased fluorescent staining of dysplastic colon cell surface QQT-cy 5.5 and anti-cMet-AF 488 (arrows) was observed in colon sections of Apc mice, fig. 15A, B. Pooled images showed co-localization of peptide and antibody binding (arrows) with correlation ρ ═ 0.78, fig. 15C. Minimal staining of the peptides and antibodies was observed in association with normal colonic mucosa, FIGS. 15D-F. The quantification results showed that the mean fluorescence intensity for dysplasia was significantly higher compared to normal colon cells, fig. 15G. The ROC curve showed 93% sensitivity and 87% specificity, and the area under the curve (AUC) of QQT x-cy 5.5 was 0.96 to distinguish dysplastic from normal tissue. Histology of mouse adenomas and normal colon is shown (H & E), fig. 15H, I.

Example 9

In vivo imaging of patient-derived colon organoids

White light images collected with the endoscope of the mice showed the presence of two normal humans (arrows, fig. 19A) and one tubular adenomatoid organ (arrows, fig. 19E) implanted in the colon of immunocompromised mice. QQT-cy 5.5 was then applied topically, incubated for about 5 minutes, and unbound peptides were washed away. The fluorescence image shows minimal signal from normal organoids (arrow, fig. 19B) and strong intensity from pre-malignant tubular adenoma organoids (arrow, fig. 19F). Fluorescence registered reflectance images were obtained (fig. 19C, G). Fluorescence images collected 3 days later from normal and adenomatous organoids using TLQ x-cy 5.5 (control) showed little signal (figure 19D, H). The statistical mean T: B ratio of QQT x-cy 5.5 was found to be significantly greater on adenomas in vivo than on normal organoids, fig. 19L. H & E histological staining of normal and adenomatous organoids is shown in figure 19J, M. IHC staining of human specific hCytokeratin on the same slide demonstrated successful transplantation of human organoids (figure 19K, N). Using these tissue sections, co-staining of cMet antibody with IF of qt-cy 5.5 showed minimal signal for normal colon (fig. 19K), while strong for adenoma organoids (fig. 19O), confirming that qt-cy 5.5 specifically binds to cMet over-expressed human tissue. The statistical results are shown in fig. 19P. Using tissue sections, using immunofluorescence, QQT x-cy 5.5 showed strong staining for adenomas and minimal staining for normal crypts, fig. 19I.

To investigate whether QQT x-cy 5.5 also bound to SSA, we generated a mouse model of SSA transplantation using the same method. White light for normal and SSA organoids is shown in fig. 16A, E (arrows). Fluorescence images collected from normal and SSA organoids are shown in fig. 16B, F (arrows). The signal on SSA was significantly higher for QQT-cy 5.5 than for normal organoids. Fluorescence registered reflectance images were obtained (fig. 16C, G). After 3 days, fluorescence images were collected from these two organoids using TLQ x-cy 5.5 (control), showing minimal signal. The statistical mean T: B ratio of QQT x-cy 5.5 was found to be significantly greater on SSA in vivo than on normal organoids, fig. 19L. H & E histological staining of normal and SSA organoids is shown in fig. 16I, M. IHC staining of human specific hCytokeratin on the same slide demonstrated successful transplantation of human organoids (figure 16J, N). Using these tissue sections, co-staining of cMet antibody and IF of QQT x-cy5.5 showed minimal signal for normal colon (fig. 19K) and strong intensity for SSA organoids (fig. 16O). Taken together, these in vivo imaging results indicate that QQT x-cy 5.5 can specifically bind to adenomas and SSA human organoids expressing cMet at high levels, as compared to normal organoids.

Example 10

Validation of cMet expression in human colon

Staining of human colon with QQT x-cy 5.5 and anti-cMet-AF 488 was evaluated in n 42 formalin-fixed, paraffin-embedded (FFPE) human colon specimens, including tubular adenomas, Sessile Serrated Adenomas (SSA), Hyperplastic Polyps (HP), and normal mucosa. Combined fluorescence images of representative sections of adenomas, SSA, Hyperplastic Polyps (HP) and normal colonic mucosa are shown, collected with a confocal microscope, fig. 6A-D. For each histological classification, co-localization of peptide and antibody binding was strong. Immunofluorescence of SSA specimens revealed large, expanded crypts with large numbers of goblet cells, indicating abnormal maturation. Immunohistochemistry was performed to verify cMet expression. Strong staining was observed for adenoma and SSA (2+/3+), while weak staining was observed for HP and normal cells (0+/1+), FIG. 6E-H. Representative histology (H & E), FIGS. 6I-L, is shown. For adenomas or SSA, the mean fluorescence intensity of qt x-cy 5.5 staining was significantly higher compared to HP or normal colon, fig. 6M. A total of n-11 SSA lesions were endoscopically described as flat in appearance, and n-2 were recorded as slightly prominent from the colonoscopy report. Representative histology (H & E), FIG. 6K-N, is shown for each histological classification.

Reference to the literature

1.Favoriti,P.,et al.Worldwide burden of colorectal cancer:a review.Updates Surg 68,7-11(2016).

2.Torre,L.A.,et al.Global cancer statistics,2012.CA Cancer J Clin 65,87-108(2015).

3.Ferlay,J.,et al.Estimates of worldwide burden of cancer in 2008:GLOBOCAN 2008.Int J Cancer 127,2893-2917(2010).

4.Ferlay,J.,et al.Cancer incidence and mortality worldwide:sources,methods and major patterns in GLOBOCAN 2012.Int J Cancer 136,E359-386(2015).

5.Brown,S.C.,Abraham,J.S.,Walsh,S.&Sykes,P.A.Risk factors and operative mortality in surgery for colorectal cancer.Ann R Coll Surg Engl 73,269-272(1991).

6.Carraro,P.G.,Segala,M.,Cesana,B.M.&Tiberio,G.Obstructing colonic cancer:failure and survival patterns over a ten-year follow-up after one-stage curative surgery.Dis Colon Rectum 44,243-250(2001).

7.Winawer,S.J.,et al.Prevention of colorectal cancer by colonoscopic polypectomy.The National Polyp Study Workgroup.N Engl J Med 329,1977-1981(1993).

8.Winawer,S.J.,et al.Randomized comparison of surveillance intervals after colonoscopic removal of newly diagnosed adenomatous polyps.The National Polyp Study Workgroup.N Engl J Med 328,901-906(1993).

9.Heresbach,D.,et al.Miss rate for colorectal neoplastic polyps:a prospective multicenter study of back-to-back video colonoscopies.Endoscopy 40,284-290(2008).

10.Soetikno,R.M.,et al.Prevalence of nonpolyploid(flat and depressed)colorectal neoplasms in asymptomatic and symptomatic adults.Jama 299,1027-1035(2008).

11.van Rijn,J.C.,et al.Polyp miss rate determined by tandem colonoscopy:a systematic review.Am J Gastroenterol 101,343-350(2006).

12.Clapper,M.L.,et al.Detection of colorectal adenomas using a bioactivatable probe specific for matrix metalloproteinase activity.Neoplasia 13,685-691(2011).

13.Marten,K.,et al.Detection of dysplastic intestinal adenomas using enzyme-sensingmolecular beacons in mice.Gastroenterology 122,406-414(2002).

14.Naran,S.,Zhang,X.&Hughes,S.J.Inhibition of HGF/MET as therapy for malignancy.Expert Opin Ther Targets 13,569-581(2009).

15.Sattler,M.&Salgia,R.cMet and hepatocyte growth factor:potential as novel targets in cancer therapy.Curr Oncol Rep 9,102-108(2007).

16.Uehara,Y.,et al.Placental defect and embryonic lethality in mice lacking hepatocyte growth factor/scatter factor.Nature 373,702-705(1995).

17.Christensen,J.G.,Burrows,J.&Salgia,R.cMet as a target for human cancer and characterization of inhibitors for therapeutic intervention.Cancer Lett 225,1-26(2005).

18.Birchmeier,C.,Birchmeier,W.,Gherardi,E.&Vande Woude,G.F.Met,metastasis,motility and more.Nat Rev Mol Cell Biol 4,915-925(2003).

19.Maulik,G.,et al.Role of the hepatocyte growth factor receptor,cMet,in oncogenesis and potential for therapeutic inhibition.Cytokine Growth Factor Rev 13,41-59(2002).

20.Di Renzo,M.F.,et al.Overexpression and amplification of the met/HGF receptor gene during the progression of colorectal cancer.Clin Cancer Res 1,147-154(1995).

21.Fearon,E.R.&Vogelstein,B.A genetic model for colorectal tumorigenesis.Cell 61,759-767(1990).

22.Lu,R.M.,Chang,Y.L.,Chen,M.S.&Wu,H.C.Single chain anti-cMet antibody conjugated nanoparticles for in vivo tumor-targeted imaging and drug delivery.Biomaterials 32,3265-3274(2011).

23.Towner,R.A.,et al.In vivo detection of cMet expression in a rat C6 glioma model.J Cell Mol Med 12,174-186(2008).

24.Joshi,B.P.,et al.Design and Synthesis of Near-Infrared Peptide for in Vivo Molecular Imaging of HER2.Bioconjug Chem 27,481-494(2016).

25.Zhou,J.,et al.EGFR Overexpressed in Colonic Neoplasia Can be Detected on Wide-Field Endoscopic Imaging.Clin Transl Gastroenterol 6,e101(2015).

26.Burggraaf,J.,et al.Detection of colorectal polyps in humans using an intravenously administered fluorescent peptide targeted against cMet.Nat Med 21,955-961(2015).

27.Sturm,M.B.,et al.Targeted imaging of esophageal neoplasia with a fluorescently labeled peptide:first-in-human results.Sci Transl Med 5,184ra161(2013).

28.Hsiung,P.L.,et al.Detection of colonic dysplasia in vivo using a targeted heptapeptide and confocal microendoscopy.Nat Med 14,454-458(2008).

29.Lee,S.,Xie,J.&Chen,X.Peptides and peptide hormones for molecular imaging and disease diagnosis.Chem Rev 110,3087-3111(2010).

30.Sato,T.,et al.Single Lgr5 stem cells build crypt-villus structures in vitro without a mesenchymal niche.Nature 459,262-265(2009).

31.Sugimoto,S.,et al.Reconstruction of the Human Colon Epithelium In Vivo.Cell Stem Cell 22,171-176 e175(2018).

32.Li,M.,et al.Affinity peptide for targeted detection of dysplasia in Barrett's esophagus.Gastroenterology 139,1472-1480(2010).

33.Fields,G.B.&Noble,R.L.Solid phase peptide synthesis utilizing 9-fluorenylmethoxycarbonyl amino acids.Int J Pept Protein Res 35,161-214(1990).

34.Thomas,R.,et al.In vitro binding evaluation of 177Lu-AMBA,a novel 177Lu-labeled GRP-R agonist for systemic radiotherapy in human tissues.Clin Exp Metastasis 26,105-119(2009).

35.Joshi,B.P.,Liu,Z.,Elahi,S.F.,Appelman,H.D.&Wang,T.D.Near-infrared-labeled peptide multimer functions as phage mimic for high affinity,specific targeting of colonic adenomas in vivo(with videos).Gastrointest Endosc 76,1197-1206 e1191-1195(2012).

36.Dame,M.K.,et al.Identification,isolation and characterization of human LGR5-positive colon adenoma cells.Development 145(2018).

37.Sato,T.,et al.Long-term expansion of epithelial organoids from human colon,adenoma,adenocarcinoma,and Barrett's epithelium.Gastroenterology 141,1762-1772(2011).

38.Tsai,Y.H.,et al.A Method for Cryogenic Preservation of Human Biopsy Specimens and Subsequent Organoid Culture.Cell Mol Gastroenterol Hepatol 6,218-222 e217(2018).

39.Miyoshi,H.&Stappenbeck,T.S.In vitro expansion and genetic modification of gastrointestinal stem cells in spheroid culture.Nat Protoc 8,2471-2482(2013).

40.Shultz,L.D.,et al.Human lymphoid and myeloid cell development in NOD/LtSz-scid IL2R gamma null mice engrafted with mobilized human hemopoietic stem cells.J Immunol 174,6477-6489(2005).

41.Ishikawa,F.,et al.Development of functional human blood and immune systems in NOD/SCID/IL2 receptor{gamma}chain(null)mice.Blood 106,1565-1573(2005).

42.Yui,S.,et al.Functional engraftment of colon epithelium expanded in vitro from a single adult Lgr5(+)stem cell.Nat Med 18,618-623(2012).

43.Xue,X.,et al.Iron Uptake via DMT1 Integrates Cell Cycle with JAK-STAT3 Signaling to Promote Colorectal Tumorigenesis.Cell Metab 24,447-461(2016).

44.Hinoi,T.,et al.Mouse model of colonic adenoma-carcinoma progression based on somatic Apc inactivation.Cancer Res 67,9721-9730(2007).

45.Liu,Z.,Miller,S.J.,Joshi,B.P.&Wang,T.D.In vivo targeting of colonic dysplasia on fluorescence endoscopy with near-infrared octapeptide.Gut 62,395-403(2013).

46.Joshi,B.P.,et al.Detection of Sessile Serrated Adenomas in the Proximal Colon Using Wide-Field Fluorescence Endoscopy.Gastroenterology 152,1002-1013 e1009(2017).

47.Rex,D.K.Reducing costs of colon polyp management.Lancet Oncol 10,1135-1136(2009).

48.Hay,R.V.,et al.Nuclear imaging of Met-expressing human and canine cancer xenografts with radiolabeled monoclonal antibodies(MetSeek).Clin Cancer Res 11,7064s-7069s(2005).

49.Jagoda,E.M.,et al.Immuno-PET of the hepatocyte growth factor receptor Met using the 1-armed antibody onartuzumab.J Nucl Med 53,1592-1600(2012).

50.Chen,K.&Chen,X.Design and development of molecular imaging probes.Curr Top Med Chem 10,1227-1236(2010).

51.Song,E.K.,et al.Potent antitumor activity of cabozantinib,a cMet and VEGFR2 inhibitor,in a colorectal cancer patient-derived tumor explant model.Int J Cancer 136,1967-1975(2015).

52.Matsumura,A.,et al.HGF regulates VEGF expression via the cMet receptor downstream pathways,PI3K/Akt,MAPK and STAT3,in CT26 murine cells.Int J Oncol 42,535-542(2013).

53.Bardelli,A.,et al.Amplification of the MET receptor drives resistance to anti-EGFR therapies in colorectal cancer.Cancer Discov 3,658-673(2013).

54.Boccaccio,C.,Luraghi,P.&Comoglio,P.M.MET-mediated resistance to EGFR inhibitors:an old liaison rooted in colorectal cancer stem cells.Cancer Res 74,3647-3651(2014).

55.Chen,J.,et al.Multiplexed Targeting of Barrett's Neoplasia with a Heterobivalent Ligand:Imaging Study on Mouse Xenograft in Vivo and Human Specimens ex Vivo.J Med Chem 61,5323-5331(2018).

56.Su et al.,Science 256(5057):668-670(1992).

57.Hinoi et al.,Cancer Res.,67(20):9721-9730(2007).

58.Alencar et al.,Radiology,244:232-238(2007).

59.Hung et al.,Proc.Natl.Acad.Sci.USA,107:1565-1570(2010).

60.Li et al.,Gastroenterology,139:1472-80(2010).

61.Hsiung et al.,Nat.Med.,14:454-458(2008).

62.Joyce et al.,Cancer Cell,4:393-403(2003).

63.Essler et al.,Proc.Natl.Acad.Sci.USA,99:2252-2257(2002).

64.Lee et al.,Mol.Cancer Res.,5(1):11-19(2007).

65.Ludtke et al.,Drug Deliv.,14:357-369(2007).

As is apparent from the context, all publications and patents mentioned in this application are herein incorporated by reference in their entirety or in relevant part. Various modifications and alterations to the disclosed subject matter will be apparent to those skilled in the art without departing from the scope and spirit of this disclosure. Although the present disclosure has been described in connection with specific embodiments, it should be understood that the invention as claimed should not be unduly limited to such specific embodiments. Indeed, various modifications of the described modes for making or using the disclosed subject matter, which are obvious to one or more of ordinary skill in the relevant art, are intended to be within the scope of the appended claims.

<110> board of the university of michigan

<120> detection of colon neoplasia in vivo using near infrared peptides targeting over-expression of cMET

<130> 30275/53791A/PC

<150> US 62/808,637

<151> 2019-02-21

<160> 3

<170> PatentIn version 3.5

<210> 1

<211> 7

<212> PRT

<213> Artificial sequence

<220>

<223> Synthesis of polypeptide

<400> 1

Gln Gln Thr Asn Trp Ser Leu

1 5

<210> 2

<211> 5

<212> PRT

<213> Artificial sequence

<220>

<223> synthetic linker

<400> 2

Gly Gly Gly Ser Lys

1 5

<210> 3

<211> 7

<212> PRT

<213> Artificial sequence

<220>

<223> Synthesis of polypeptide

<400> 3

Thr Leu Gln Trp Asn Gln Ser

1 5

Claims (22)

1. A peptide comprising SEQ ID NO:1, QQTNWSL.

2. The peptide of claim 1, wherein the peptide is derivatized.

3. The peptide of claim 2, wherein the peptide is derivatized by linking to a linker.

4. The peptide of claim 3, wherein the linker comprises SEQ ID NO:2, GGGSK.

5. The peptide of claim 2, wherein the derivatized peptide is labeled.

6. The peptide of claim 5, wherein the peptide label is a fluorescent label.

7. The peptide of claim 5, wherein the label is FITC, Cy5.5, Cy7, Li-Cor, a radiolabel, biotin, luciferase, 1,8-ANS (1-anilinonaphthalene-8-sulfonic acid), 1-anilinonaphthalene-8-sulfonic acid (1,8-ANS), 5- (and-6) -carboxy-2 ',7' -dichlorofluorescein pH9.0, 5-FAM pH9.0, 5-ROX (5-carboxy-X-rhodamine, triethylammonium salt), 5-ROX pH7.0, 5-TAMRA pH7.0, 5-TAMRA-MeOH, 6JOE, 6, 8-difluoro-7-hydroxy-4-methylcoumarin pH9.0, 6-carboxyrhodamine 6G pH7.0, 6-carboxyrhodamine 6G, HCl, 6-HEX, SE pH9.0, 6-TET, SE pH9.0, 7-amino-4-methylcoumarin pH7.0, 7-hydroxy-4-methylcoumarin pH9.0, Alexa 350, Alexa 405, Alexa 430, Alexa 488, Alexa 532, Alexa 546, Alexa 555, Alexa 568, Alexa 594, Alexa 647, Alexa 660, Alexa 680, Alexa 700, Alexa Fluor 430 antibody conjugate pH 7.2, Alexa Fluor 488 antibody conjugate pH 8.0, Alexa Fluor 488 hydrazide-water, Alexa Fluor 532 antibody conjugate pH 7.2, Alexa Fluor 555 antibody conjugate pH 7.2, Alexa Fluor 568 antibody conjugate pH 7.2, Alexa Fluor 610-phycoerythrin pH 7.2 Alexa Fluor 647 antibody conjugate pH 7.2, Alexa Fluor 647R-phycoerythrin streptavidin pH 7.2, Alexa Fluor 660 antibody conjugate pH 7.2, Alexa Fluor 680 antibody conjugate pH 7.2, Alexa Fluor 700 antibody conjugate pH 7.2, allophycocyanin pH 7.5, AMCA conjugate, aminocoumarin, APC (allophycocyanin), Atto 647, BCECF pH 5.5, BcaCt,BCECF pH9.0, BFP (blue fluorescent protein), calcein pH9.0, calcein Ca2+, calcein Ca2+, calcein, caloranic Ca2+, carboxynaphthofluorescein pH 10.0, cascade blue BSA pH7.0, cascade yellow antibody conjugate pH 8.0, CFDA, CFP (cyan fluorescent protein), CI-NERF pH 2.5, CI-NERF pH6.0, amethyst, coumarin, Cy 2, Cy 3, Cy 3.5, CyQUANT GR-DNA, dansyl cadaverine, MeOH, PI, DAPI-DNA, Dapoxyl (2-aminoethyl) sulfonamide, DDpH 9.0, sRS-8 ANEPPS, Di-8-ANEPPS-lipid, DiI, DiNEO, DM-RF pH 4.0, DM-RF 7.0, DRF-pH 0, DAF 0, D-D AF, D3.0, D3, and D3, dTomato, eCPP (enhanced cyan fluorescent protein), eGFP (enhanced green fluorescent protein), eosin antibody conjugate pH 8.0, erythrosine-5-isothiocyanate pH9.0, eYFP (enhanced yellow fluorescent protein), FDA, FITC antibody conjugate pH 8.0, FluSH, Fluo-3 Ca2⁺Fluo-4, Fluor-Ruby, fluorescein 0.1M NaOH, fluorescein antibody conjugate pH 8.0, fluorescein dextran pH 8.0, fluorescein pH9.0, Fluoro-Emerald, FM 1-43 lipids, FM 4-64, 2% CHAPS, Fura Red Ca2⁺Fura Red, high Ca, Fura Red, low Ca, Fura-2 Ca2+, Fura-2, GFP (S65T), HcRed, Indo-1Ca2⁺Indo-1, Ca-free, Indo-1, Ca saturated, JC-1pH 8.2, lissamine rhodamine, fluorescein, CH, magnesium green Mg2+, magnesium orange, Marina Blue, mBanana, mCherry, mHoneyde, mOrange, mPlum, mRFP, mStrawberry, mTangerine, NBD-X, NBD-X, MeOH, NeuroTrace 500/525, green fluorescent Nile-stained RNA, Nile Blue, Nile Red, Nissl, Oregon Green 488 antibody conjugate pH 8.0, Oregon Green 514 antibody conjugate pH 8.0, Pacific Blue antibody conjugate pH 8.0, Rhor phycoerythrin, R-phycoerythrin pH 7.5, AsH, Aregon 630, Halogen Blue antibody conjugate, Rhodin 2-Ca 2-52, Rhor 2-Hairin-2-Ca 2-2⁺Rhodamine, rhodamine 110pH 7.0, rhodamine 123, MeOH, rhodamine Green, rhodamine ghost cyclic peptide pH7.0, rhodamine Red-X antibody conjugate pH 8.0, rhodamine Green pH7.0, Rhodol Green antibodyConjugate pH 8.0, sapphire, SBFI-Na⁺Sodium hyaluronate Na⁺Sulfonylrhodamine 101, tetramethylrhodamine antibody conjugate pH 8.0, tetramethylrhodamine dextran pH7.0, Texas Red-X antibody conjugate pH 7.2,¹¹C、¹³N、¹⁵O、¹⁸F、³²P、⁵²Fe、⁶²Cu、⁶⁴Cu、⁶⁷Cu、⁶⁷Ga、⁶⁸Ga、⁸⁶Y、⁸⁹Zr、⁹⁰Y、⁹⁴mTc、⁹⁴Tc、⁹⁵Tc、⁹⁹mTc、¹⁰³Pd、¹⁰⁵Rh、¹⁰⁹Pd、¹¹¹Ag、¹¹¹In、¹²³I、¹²⁴I、¹²⁵I、¹³¹I、¹⁴⁰La、¹⁴⁹Pm、¹⁵³Sm、^154-159Gd、¹⁶⁵Dy、¹⁶⁶Dy、¹⁶⁶Ho、¹⁶⁹Yb、¹⁷⁵Yb、¹⁷⁵Lu、¹⁷⁷Lu、¹⁸⁶Re、¹⁸⁸Re、¹⁹²Ir、¹⁹⁸Au、¹⁹⁹Au or²¹²Bi。

8. The peptide of claim 6, wherein the fluorescent label emits in the near infrared range of the electromagnetic spectrum.

9. The peptide of claim 6, wherein the fluorescent label is FITC or a cyanine dye.

10. The peptide of claim 9, wherein the cyanine dye is Cy5.5 or Cy 7.

11. The peptide of claim 1 consisting of SEQ ID NO: 1.

12. A method of detecting intestinal neoplasia comprising:

(a) and contacting the intestinal tissue with a polypeptide comprising SEQ ID NO:1 with a labeled peptide of the sequence listed in seq id no;

(b) measuring binding of the labeled peptide to the intestinal tissue; and

(c) detecting intestinal neoplasia based on the measurement of binding.

13. The method of claim 12, wherein the intestinal tissue is colorectal tissue.

14. The method of claim 13, wherein the colorectal tissue is colon tissue.

15. The method of claim 12, wherein the intestinal neoplasia is a precancerous lesion.

16. The method of claim 12, wherein the intestinal neoplasia is cancer.

17. The method of claim 16, wherein the cancer is colorectal cancer.

18. The method of claim 12, wherein the intestinal tissue bound to the labeled peptide is indistinguishable as a polyp by endoscopy.

19. The method of claim 12, wherein the intestinal tissue is a polyp.

20. The method of claim 12, wherein the binding occurs in vivo.

21. The method of claim 12, further comprising in vivo fluorescence imaging.

22. The method of claim 21, wherein the fluorescence imaging is obtained using a wide area endoscope.

Images